Bit Block Stream Bit Error Detection Method and Device

ABSTRACT

A method includes: sending a first boundary bit block; sequentially sending an Ith bit block; determining a first parity check result and a second parity check result, where a check object of the first parity check result includes m consecutive bits of each bit block in the N bit blocks, a check object of the second parity check result includes n consecutive bits of each bit block in the N bit blocks, and at least one of m and n is greater than or equal to 2; and sending a second boundary bit block, the first parity check result, and the second parity check result.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/692,151, filed on Nov. 22, 2019, now U.S. Pat. No. 10/992,315, whichis a continuation of International Application No. PCT/CN2018/086326,filed on May 10, 2018. The International Application claims priority toChinese Patent Application No. 201710764932.7, filed on Aug. 30, 2017and Chinese Patent Application No. 201710374518.5, filed on May 24,2017. All of the afore-mentioned patent applications are herebyincorporated by reference in their entireties.

TECHNICAL FIELD

This application relates to the field of communications technologies,and in particular, to a bit block stream bit error detection method anddevice.

BACKGROUND

In a current technology, a plurality of methods for performing bit errordetection based on a packet are proposed. For example, cyclic redundancycheck (CRC) detection is performed based on a packet. An error packet isdetermined based on a frame check sequence (FCS) field (CRC-32) of eachEthernet packet, and quality of a user channel can be evaluated bycollecting statistics on a packet error rate within a period of time.However, in the foregoing manner, a bit error rate (BER) cannot beaccurately measured. When there is no user service packet, a BER cannotbe measured; or when there are few user service packets, it takes a longtime to detect a BER.

For example, if one FCS check error in an Ethernet packet is consideredas one bit error, at least 100,000 Ethernet packets need to becontinuously sent, received, and detected to evaluate a BER of 1*e−5. Ifuser service bandwidth is 10 Mbps, the Ethernet packets are sent at fulltraffic, and a length of the Ethernet packets is 256 B, a detection timeis at least 22.08 seconds. If user service bandwidth is only 100 Kbps,and a length of the Ethernet packets is 256 B, a detection time is atleast 36.8 minutes (2,208 seconds).

As shown in Table 1, an FCS occupies four bytes. Therefore, anotherproblem of the foregoing method is that a relatively larger quantity offixed frame bytes are occupied and relatively low bearer efficiency iscaused. If a CRC-32 check is introduced, when a minimum packet is 64 B,bearer efficiency decreases by 6.25%; or when a maximum packet is 1518B, bearer efficiency decreases by 0.263%.

TABLE 1 Preamble SFD Destination Source Length/Type Data and Pad FCS 7 16 6 2 46-1,500 4

In addition, a bit error detection method using bit interleaved parity(BIP) on a per-frame basis is further proposed in the currenttechnology. For example, a BIP check overhead byte is set in a framestructure of a synchronous digital hierarchy SDH (SDH)/an opticaltransport network (OTN). Therefore, bearer efficiency of this method isrigid, and a check algorithm cannot be dynamically defined according toa user requirement. For example, BIP-8 cannot be degraded to BIP-4 orupgraded to BIP-16.

Currently, a 5th generation (5G) communications technology has beenwidely studied in the industry, and deterministic low latency,reliability, and security isolation technologies have become importanttasks to be tackled by 5G urgently. X-Ethernet (X-E for short) is a bitblock switching technology based on an Ethernet physical layer, forexample, a 64/66 bit block, and has a technical characteristic ofdeterministic ultra-low latency. Based on M/N bit block switching,X-Ethernet can perform bit error detection by using the foregoing biterror detection method. For example, the following two methods may beincluded.

Method 1: By using a packet-based CRC detection method, X-E arrangesseveral bits to perform a CRC check block by block. For example, for a66 bit block, four or eight bits may be set to perform a CRC check onother 60 or 56 bits.

Method 2: By using SDH/OTN manner, one byte or several bits are arrangedto perform a BIP check block by block. For example, for a 66 bit block,two to eight bits may be set to perform a BIP check on other 62 to 56bits.

Although the foregoing two methods can be implemented, a processing unitin a device needs to perform an operation block by block in either ofthe methods, and therefore the methods are difficult to implement. Inaddition, bearer efficiency of the foregoing two methods is relativelylow. For example, if a BIP-4/CRC-4 check is performed on each block,bearer efficiency decreases by 6.25%; or if a BIP-8/CRC-8 check isperformed on each block, bearer efficiency decreases by 12.5%.

SUMMARY

Embodiments of this application provide a bit block stream bit errordetection method and device, to resolve problems of relatively highimplementation difficulty and relatively low bearer efficiency of a biterror detection method in an M/N bit block switching scenario.

According to a first aspect, a bit block stream bit error detectionmethod is provided, including: sending a first boundary bit block, wherethe first boundary bit block is used to distinguish N bit blocks to besubsequently sent, and N is a positive integer; sequentially sending anIth bit block, where I is an integer greater than or equal to 1 and lessthan or equal to N; determining a first parity check result and a secondparity check result, where a check object of the first parity checkresult includes m consecutive bits of each bit block in the N bitblocks, a check object of the second parity check result includes nconsecutive bits of each bit block in the N bit blocks, and at least oneof m and n is greater than or equal to 2; and sending a second boundarybit block, the first parity check result, and the second parity checkresult, where the second boundary bit block is used to distinguish the Nbit blocks that have been sent.

Therefore, by using the method provided in this embodiment of thisapplication, error or bit error detection on a network path of an M/Nbit block can be fully implemented, with no impact on a user service;bearer efficiency is 100%, and a bit block that is inserted or deleteddue to synchronization in a transfer process can be tolerated; inaddition, a detection period (that is, a quantity of bit blocks betweenthe two boundary bit blocks) and detection precision (that is, a presetalgorithm) can be dynamically configured according to a requirement. Inaddition, the detection method can not only be used for a to-be-checkedbit block stream whose path is an end-to-end path, but can also be usedfor a to-be-checked bit block stream whose path is a non-end-to-endpath. Therefore, by using the method provided in this embodiment of thisapplication, problems of relatively high implementation difficulty andrelatively low bearer efficiency of a bit error detection method in anM/N bit block switching scenario can be resolved.

It should be understood that, when a path of a to-be-checked bit blockstream is from a bit block transmit end to a bit block receive end, orwhen a path of the to-be-checked bit block stream is from the bit blocktransmit end to any intermediate device before the bit block receiveend, the foregoing method may be performed by the bit block transmitend. When the path of the to-be-checked bit block stream is from the bitblock transmit end to the bit block receive end, the path of theto-be-checked bit block stream is an end-to-end path. When the path ofthe to-be-checked bit block stream is from the bit block transmit end toany intermediate device before the bit block receive end, the path ofthe to-be-checked bit block stream is a path with one end unconnected.The bit block transmit end is referred to as a transmitting devicethroughout this application. Therefore, this embodiment of thisapplication can not only be used to perform bit error detection on anend-to-end path, but can also be used to perform bit error detection ona non-end-to-end path, for example, a planned reserved path, aprotection path of a 1:1 connection protection group, or a path foranother special purpose. When the path of the to-be-checked bit blockstream is from a first intermediate device after the bit block transmitend to a second intermediate device before the bit block receive end,the foregoing method may be performed by the first intermediate device.The path of the to-be-checked bit block stream is a path with both endsunconnected.

In a possible design, a type of each bit block is an M1/M2 bit block, M1indicates a quantity of payload bits in each bit block, M2 indicates atotal quantity of bits in each bit block, M2−M1 indicates a quantity ofsynchronization header bits at a header of each bit block, M1 and M2 arepositive integers, and M2 >M1.

In a possible design, the sending a first boundary bit block includes:sending the first boundary bit block to a first device; the sequentiallysending an Ith bit block includes: sequentially sending the Ith bitblock to the first device; and the sending a second boundary bit block,the first parity check result, and the second parity check result mayinclude the following two cases: (1) The second boundary bit block, thefirst parity check result, and the second parity check result are sentto the first device. Therefore, in the foregoing implementation, thefirst parity check result and the second parity check result are senttogether with the two boundary bit blocks and the N bit blocks betweenthe two boundary bit blocks to the first device. When the path of theto-be-checked bit block stream is from the bit block transmit end to thebit block receive end, the first device herein may be the bit blockreceive end; or when the path of the to-be-checked bit block stream isfrom the bit block transmit end to any intermediate device before thebit block receive end, or when the path of the to-be-checked bit blockstream is from a first intermediate device after the bit block transmitend to a second intermediate device before the bit block receive end,the first device herein may also be the intermediate device. (2) Thesecond boundary bit block is sent to the first device, and the firstparity check result and the second parity check result are sent to asecond device. It should be known that the second device herein may bean SDN controller, or any device that has a function of determining abit error in bit stream transmission. In addition, the two manners maybe used herein at the same time. That is, the first parity check resultand the second parity check result are sent to both the first device andthe second device. Therefore, this embodiment of this applicationprovides two optional manners, to implement bit error detection, and thebit error detection is more flexible and efficient, and simple andconvenient to implement.

In a possible design, sending the second boundary bit block, the firstparity check result, and the second parity check result is implementedin the following several possible manners: sending the second boundarybit block at a first moment, and sending the first parity check resultand the second parity check result at a second moment, where the firstmoment is earlier than the second moment, or the first moment is laterthan the second moment, or the first moment is the same as the secondmoment.

In a possible design, the first parity check result and the secondparity check result are stored in the second boundary bit block.

Therefore, assuming that every N bit blocks in the bit block stream formone group, an i^(th) boundary bit block stores a first parity checkresult and a second parity check result that correspond to N bit blocksin an i^(th) group, and an (i+1)^(th) boundary bit block stores a firstparity check result and a second parity check result that correspond toN bit blocks in an (i+1)^(th) group, where the N bit blocks in the(i+1)^(th) group are bit blocks between the i^(th) boundary bit blockand the (i+1)^(th) boundary bit block, and i is a positive integer.

It should be understood that the boundary bit block mentioned in thisapplication may be a newly inserted bit block; when a new boundary bitblock is inserted, a first bit block may be deleted, to reduce impact onuser bandwidth, where the first bit block is a bit block that may beinserted into the N bit blocks or deleted from the N bit blocks in atransmission process of the N bit blocks. For example, for a 64/66 bitblock stream, the first bit block may be an idle block.

In a possible design, the first parity check result and the secondparity check result are calculated based on a preset check algorithm,where the preset check algorithm is used to keep the first parity checkresult and the second parity check result unchanged when the first bitblock is added to or removed from the N bit blocks, and the first bitblock is a bit block that may be inserted into the N bit blocks ordeleted from the N bit blocks in the transmission process of the N bitblocks. Therefore, by using the preset check algorithm provided in thisembodiment of this application, it can be ensured that the first paritycheck result and the second parity check result can tolerate one or morefirst bit blocks (for example, IDLE Blocks) that are inserted or deletedin the transmission process, and a bit error occurring in the first bitblock can also be detected.

In a possible design, the preset check algorithm is an xBIP-y algorithm,where x indicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y≥2. For example, the preset check algorithm may be an 8BIP-8 algorithm or a 16 BIP-4 algorithm. A specific method fordetermining the first parity check result and the second parity checkresult by using the xBIP-y algorithm is: sequentially recording every xconsecutive bits of each bit block into a first monitoring section to ay^(th) monitoring section from a first payload bit in the N bit blocks;and determining a 1-bit monitoring code for each monitoring section byusing an odd parity check or an even parity check, to obtain a y-bitmonitoring code, where the y-bit monitoring code includes the firstparity check result and the second parity check result. Therefore, byusing the xBIP-y algorithm provided in this embodiment of thisapplication, and one or more first bit blocks that are inserted ordeleted in the transmission process can be tolerated. The method issimple and convenient.

In a possible design, the preset check algorithm is a flexBIP-zalgorithm, z indicates a quantity of monitoring sections, not allquantities of consecutive bit-interleaved bits corresponding to themonitoring sections are the same, and the quantities of consecutivebit-interleaved bits respectively corresponding to the z monitoringsections are A1, A2, A3, . . . , Az−1, and Az, where A1, A2, A3, . . . ,Az−1, and Az, and z are positive integers, and z ≥2; and a specificmethod for determining the first parity check result and the secondparity check result by using the flexBIP-z algorithm is: recording A1consecutive bits of each bit block into a first monitoring section froma first payload bit in the N bit blocks, recording A2 consecutive bitsafter the A1 consecutive bits into a second monitoring section, andrecording A3 consecutive bits after the A2 consecutive bits into a thirdmonitoring section, until Az consecutive bits after Az−1 consecutivebits are recorded into a zth monitoring section; and determining a1-bitmonitoring code for each monitoring section by using an odd parity checkor an even parity check, to obtain a z-bit monitoring code, where thez-bit monitoring code includes the first parity check result and thesecond parity check result. Therefore, by using the flexBIP-z algorithmprovided in this embodiment of this application, the first parity checkresult and the second parity check result can be determined moreflexibly and simply, and one or more first bit blocks that are insertedor deleted in the transmission process can be tolerated.

In a possible design, the determining the first parity check result andthe second parity check result includes: determining a first checkresult set, where the first check result set includes the y-bitmonitoring code, or the first check result set includes the z-bitmonitoring code; and the sending the first parity check result and thesecond parity check result includes: sending the first check result set.Therefore, by using the method provided in this embodiment of thisapplication, error or bit error detection on a network path of an M/Nbit block can be fully implemented.

According to a second aspect, a bit block stream bit error detectionmethod is provided, including: receiving a first boundary bit block,where the first boundary bit block is used to distinguish T bit blocksto be subsequently received, and T is a positive integer; sequentiallyreceiving an Ith bit block, where I is an integer greater than or equalto 1 and less than or equal to T; receiving a second boundary bit block,where the second boundary bit block is used to distinguish the T bitblocks that have already been received; determining a third parity checkresult and a fourth parity check result, where a check object of thethird parity check result includes m consecutive bits of each bit blockin the T bit blocks, a check object of the fourth parity check resultincludes n consecutive bits of each bit block in the T bit blocks, andat least one of m and n is greater than or equal to 2; and when a firstparity check result and a second parity check result are received,determining, based on the first parity check result and the third paritycheck result, and the second parity check result and the fourth paritycheck result, whether a bit error exists in the T bit blocks, where acheck object of the first parity check result includes m consecutivebits of each bit block in N bit blocks, a check object of the secondparity check result includes n consecutive bits of each bit block in theN bit blocks, and N indicates a quantity of bit blocks between the firstboundary bit block and the second boundary bit block when the firstparity check result and the second parity check result are determined.Therefore, by using the method provided in this embodiment of thisapplication, error or bit error detection on a network path of an M/Nbit block can be fully implemented, with no impact on a user service;bearer efficiency is 100%, and a bit block that is inserted or deleteddue to synchronization in a transfer process can be tolerated; inaddition, a detection period (that is, a quantity of bit blocks betweenthe two boundary bit blocks) and detection precision (that is, a presetalgorithm) can be dynamically configured according to a requirement. Inaddition, the detection method can not only be used for a to-be-checkedbit block stream whose path is an end-to-end path, but can also be usedfor a to-be-checked bit block stream whose path is a non-end-to-endpath. Therefore, by using the method provided in this embodiment of thisapplication, problems of relatively high implementation difficulty andrelatively low bearer efficiency of a bit error detection method in anM/N bit block switching scenario can be resolved.

It should be understood that, when the path of the to-be-checked bitblock stream is from a bit block transmit end to a bit block receiveend, steps in FIG. 13 may be performed by the bit block receive end; orwhen the path of the to-be-checked bit block stream is from the bitblock transmit end to any intermediate device before the bit blockreceive end, or when the path of the to-be-checked bit block stream isfrom the bit block transmit end to the bit block receive end, theforegoing method may be performed by the intermediate device. The bitblock receive end is referred to as a receiving device throughout thisapplication.

It should be known that the N bit blocks herein are bit blocks betweenthe first boundary bit block and the second boundary bit block when atransmitting device determines the first parity check result and thesecond parity check result. In an optional embodiment, after sending thefirst boundary bit block, the transmitting device sequentially sends theN bit blocks, then calculates the first parity check result and thesecond parity check result based on the N bit blocks, stores the tworesults into the second boundary bit block, and sends the secondboundary bit block. However, considering that a path from thetransmitting device to the receiving device needs to pass through anasynchronous node, a first bit block may be inserted into or deletedfrom the N bit blocks. After receiving the first boundary bit block, thereceiving device sequentially receives the T bit blocks, and then threecases may occur: N=T, or N>T (which means that the first bit block isinserted into the N bit blocks), or N<T (which means that the first bitblock is deleted from the N bit blocks).

In a possible design, the method further includes: when a first paritycheck result and a second parity check result are not received, sendingthe third parity check result and the fourth parity check result to asecond device, where the second device stores the first parity checkresult and the second parity check result. It should be known that thesecond device herein may be an SDN controller, or any device that has afunction of determining a bit error in bit stream transmission. Inaddition, when the first parity check result and the second parity checkresult are received, the third parity check result and the fourth paritycheck result may also be sent to the second device. Therefore, thesecond device may receive the first parity check result and the secondparity check result that are sent by the transmitting device, and thethird parity check result and the fourth parity check result that aresent by the receiving device, and the second device determines, based onthe two sets of results, whether a bit error exists in a transmissionprocess of the bit block stream. Therefore, this embodiment of thisapplication provides implementation of bit error detection by athird-party device, for example, an SDN controller, or any device thathas a function of determining a bit error in bit stream transmission,and the bit error detection is more flexible and efficient, and simpleand convenient to implement.

In a possible design, a type of each bit block is an M1/M2 bit block, M1indicates a quantity of payload bits in each bit block, M2 indicates atotal quantity of bits in each bit block, M2−M1 indicates a quantity ofsynchronization header bits at a header of each bit block, M1 and M2 arepositive integers, and M2 >M1.

In a possible design, the receiving a second boundary bit blockincludes: receiving the second boundary bit block at a first moment; andreceiving the first parity check result and the second parity checkresult includes: receiving the first parity check result and the secondparity check result at a second moment, where the first moment isearlier than the second moment, or the first moment is later than thesecond moment, or the first moment is the same as the second moment.

In a possible design, the first parity check result and the secondparity check result are stored in the second boundary bit block.

In a possible design, the third parity check result and the fourthparity check result are calculated based on a preset check algorithm,where the preset check algorithm is used to keep the third parity checkresult and the fourth parity check result unchanged when the first bitblock is added to or removed from the T bit blocks, and the first bitblock is a bit block that may be inserted into the T bit blocks ordeleted from the T bit blocks in a transmission process of the T bitblocks. Therefore, by using the preset check algorithm provided in thisembodiment of this application, it can be ensured that the first paritycheck result and the second parity check result can tolerate one or morefirst bit blocks (for example, IDLE Blocks) that are inserted or deletedin the transmission process, and a bit error occurring in the first bitblock can also be detected.

In addition, it should be understood that a preset algorithm used whenthe receiving device determines the third parity check result and thefourth parity check result is the same as a preset algorithm used whenthe transmitting device determines the first parity check result and thesecond parity check result. Same parts are not described again.

In a possible design, the preset check algorithm is an xBIP-y algorithm,where x indicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y ≥2.

The determining a third parity check result and a fourth parity checkresult includes: sequentially recording every x consecutive bits of eachbit block into a first monitoring section to a y^(th) monitoring sectionfrom a first payload bit in the T bit blocks; and determining a 1-bitmonitoring code for each monitoring section by using an odd parity checkor an even parity check, to obtain a y-bit monitoring code, where they-bit monitoring code includes the third parity check result and thefourth parity check result. Therefore, by using the xBIP-y algorithmprovided in this embodiment of this application, and one or more firstbit blocks that are inserted or deleted in the transmission process canbe tolerated. The method is simple and convenient.

In a possible design, the preset check algorithm is a flexBIP-zalgorithm, z indicates a quantity of monitoring sections, not allquantities of consecutive bit-interleaved bits corresponding to themonitoring sections are the same, and the quantities of consecutivebit-interleaved bits respectively corresponding to the z monitoringsections are A1, A2, A3, . . . , and Az, where A1, A2, A3, . . . , Az−1,and Az, and z are positive integers, and z 2; and the determining athird parity check result and a fourth parity check result includes:recording A1 consecutive bits of each bit block into a first monitoringsection, recording A2 consecutive bits after the A1 consecutive bitsinto a second monitoring section, and recording A3 consecutive bitsafter the A2 consecutive bits into a third monitoring section from afirst payload bit in the T bit blocks, until Az consecutive bits afterAz−1 consecutive bits are recorded into a zth monitoring section; anddetermining a 1-bit monitoring code for each monitoring section by usingan odd parity check or an even parity check, to obtain a z-bitmonitoring code, where the z-bit monitoring code includes the thirdparity check result and the fourth parity check result. Therefore, byusing the flexBIP-z algorithm provided in this embodiment of thisapplication, the first parity check result and the second parity checkresult can be determined more flexibly and simply, and one or more firstbit blocks that are inserted or deleted in the transmission process canbe tolerated.

In a possible design, the determining, based on the first parity checkresult and the third parity check result, and the second parity checkresult and the fourth parity check result, whether a bit error exists inthe T bit blocks includes: if it is determined that the first paritycheck result is the same as the third parity check result, and thesecond parity check result is the same as the fourth parity checkresult, determining that no bit error exists in the T bit blocks; or ifit is determined that the first parity check result is different fromthe third parity check result, and/or the second parity check result isdifferent from the fourth parity check result, determining that a biterror exists in the T bit blocks.

In a possible design, receiving the first parity check result and thesecond parity check result includes: receiving a first check result set,where the first check result set is calculated based on an xBIP-yalgorithm, and a y-bit monitoring code included in the first checkresult set includes the first parity check result and the second paritycheck result; and the determining a third parity check result and afourth parity check result includes: determining a second check resultset, where the second parity check result set is calculated based on thexBIP-y algorithm, and a y-bit monitoring code included in the secondcheck result set includes the third parity check result and the fourthparity check result; and when the first parity check result and thesecond parity check result are received, the determining, based on thefirst parity check result and the third parity check result, and thesecond parity check result and the fourth parity check result, whether abit error exists in the T bit blocks includes: determining, based on thefirst check result set and the second check result set, whether a biterror exists in the T bit blocks. Therefore, by using the methodprovided in this embodiment of this application, error or bit errordetection on a network path of an M/N bit block can be fullyimplemented.

In a possible design, receiving the first parity check result and thesecond parity check result includes: receiving a first check result set,where the first check result set is calculated based on the flexBIP-zalgorithm, and a z-bit monitoring code included in the first checkresult set includes the first parity check result and the second paritycheck result; and the determining a third parity check result and afourth parity check result includes: determining a second check resultset, where the second check result set is calculated based on theflexBIP-z algorithm, and a z-bit monitoring code included in the secondcheck result set includes the third parity check result and the fourthparity check result; and when the first parity check result and thesecond parity check result are received, the determining, based on thefirst parity check result and the third parity check result, and thesecond parity check result and the fourth parity check result, whether abit error exists in the T bit blocks includes: determining, based on thefirst check result set and the second check result set, whether a biterror exists in the T bit blocks. Therefore, by using the methodprovided in this embodiment of this application, error or bit errordetection on a network path of an M/N bit block can be fullyimplemented.

In a possible design, the determining, based on the first check resultset and the second check result set, whether a bit error exists in the Tbit blocks includes: if it is determined that the first check result setis the same as the second check result set, determining that no biterror exists in the T bit blocks; or if it is determined that the firstcheck result set is different from the second check result set,determining that a bit error exists in the T bit blocks.

According to a third aspect, a bit block stream bit error detectionmethod is provided, including: determining, by a first device, ato-be-detected section based on a start byte in a start block in a bitblock stream and an end byte in an end block corresponding to the startblock; and calculating, by the first device, a first check result basedon the to-be-detected section; and sending, by the first device, thefirst check result and the bit block stream. For example, an algorithmused when the first device calculates the first check result may beCRC-x or BIP-x. The first check result is recorded as B, and B may beone or more bytes. Therefore, by using the method provided in thisembodiment of this application, error or bit error detection on anetwork path of an M/N bit block can be fully implemented, with littleimpact on a user service; bearer efficiency is close to bearerefficiency of SDH/OTN, and superior to bearer efficiency of a bit errordetection method provided in the current technology; and animplementation procedure is simple, and easy to implement.

In a possible design, the bit block stream includes at least one M1/M2bit block, where M1 indicates a quantity of payload bits in each bitblock, M2 indicates a total quantity of bits in each bit block, M2−M1indicates a quantity of synchronization header bits at a header of eachbit block, M1 and M2 are positive integers, and M2 >M1.

In a possible design, the sending, by the first device, the first checkresult and the bit block stream includes: sending, by the first device,the first check result and the bit block stream to a second device; orsending, by the first device, the first check result to a third device,and sending the bit block stream to the second device. Therefore, thisembodiment of this application provides implementation of bit errordetection by a third-party device, for example, an SDN controller, orany device that has a function of determining a bit error in bit streamtransmission, and the bit error detection is more flexible andefficient, and simple and convenient to implement.

In a possible design, before the sending, by the first device, the firstcheck result and the bit block stream to a second device, the methodfurther includes: storing, by the first device, the first check resultinto the end block, to obtain an updated end block; or storing, by thefirst device, the first check result into a check result storage block,and deleting any first bit block in the bit block stream, where thecheck result storage block is a newly added block located before the endblock, and the first bit block is a bit block that may be inserted intothe bit block stream or deleted from the bit block stream in atransmission process of the bit block stream. Therefore, this embodimentof this application provides two methods for storing the first checkresult, and the storage methods are more flexible, and simple andconvenient to implement.

In a possible design, the storing, by the first device, the first checkresult into the end block, to obtain an updated end block includes: whena quantity of bytes occupied by the first check result is greater thanor equal to a quantity of target bytes, storing, by the first device,the first check result at a position before the end byte in the endblock, moving the end byte into a newly added block after the end blockbased on the quantity of bytes occupied by the first check result,deleting any first bit block in the bit block stream, and using thenewly added block in which the end byte is located after being moved asan updated end block; or when a quantity of bytes occupied by the firstcheck result is less than the quantity of target bytes, storing, by thefirst device, the first check result at a position before the end bytein the end block, backward moving, based on the quantity of bytesoccupied by the first check result, the end byte by the quantity ofbytes occupied by the first check result, and using a bit block in whichthe end byte is located after being moved as an updated end block, wherethe quantity of target bytes is 1 plus a quantity of bytes located afterthe end byte in the end block. Therefore, by using the method providedin this embodiment of this application, implementation is simple andconvenient.

According to a fourth aspect, a bit block stream bit error detectionmethod is provided, including: determining, by a second device, ato-be-detected section based on a start byte in a start block in a bitblock stream and an end byte in an end block corresponding to the startblock; calculating, by the second device, a second check result based onthe to-be-detected section; and when the second device receives a firstcheck result, determining, by the second device based on the first checkresult and the second check result, whether a bit error exists in theto-be-detected section. Therefore, by using the method provided in thisembodiment of this application, error or bit error detection on anetwork path of an M/N bit block can be fully implemented, with littleimpact on a user service; bearer efficiency is close to bearerefficiency of SDH/OTN, and superior to bearer efficiency of a bit errordetection method provided in the current technology; and animplementation procedure is simple, and easy to implement.

An algorithm used when the second device calculates the second checkresult is the same as that used when a first device calculates the firstcheck result.

In a possible design, the bit block stream includes at least one Mi/M2bit block, where M1 indicates a quantity of payload bits in each bitblock, M2 indicates a total quantity of bits in each bit block, M2−M1indicates a quantity of synchronization header bits at a header of eachbit block, M1 and M2 are positive integers, and M2 >M1.

In a possible design, the determining, by a second device, ato-be-detected section based on a start byte in a start block in a bitblock stream and an end byte in an end block corresponding to the startblock includes three possible cases: (1) If the second device receivesthe first check result, and the first check result is stored in the endblock, the second device deletes the first check result from the endblock, to obtain an updated end block, and uses bytes between the startbyte in the start block and an end byte in the updated end block as theto-be-detected section. (2) If the second device receives the firstcheck result, and the first check result is stored in a check resultstorage block, the second device deletes the check result storage blockfrom the bit block stream, to obtain an updated bit block stream, anduses bytes between the start byte in the start block in the updated bitblock stream and the end byte in the end block as the to-be-detectedsection, where the check result storage block is located before the endblock. In the foregoing two cases, the first check result is included inthe bytes between the start byte in the start block and the end byte inthe end block. Therefore, the first check result needs to be firstdeleted, and a remaining part is used as the to-be-detected detection.In addition, if the second device receives the first check result, andthe first check result is stored in the check result storage block, thesecond device deletes the check result storage block from the bit blockstream, to obtain the updated bit block stream, where the check resultstorage block is located before the end block. At the same time, toreduce impact on user bandwidth, a first bit block needs to be addedafter the end block. (3) If the second device does not receive the firstcheck result, the second device uses bytes between the start byte in thestart block in the bit block stream and the end byte in the end block asthe to-be-detected section. In this case, the first check result is notincluded in the bytes between the start byte in the start block and theend byte in the end block, so that the bytes can be directly used as theto-be-detected section.

In a possible design, the method further includes: if the second devicedoes not receive the first check result, sending, by the second device,the second check result to a third device, where the third device storesthe first check result. Therefore, this embodiment of this applicationprovides two methods for storing the first check result, and the storagemethods are more flexible, and simple and convenient to implement.

In a possible design, the determining, by the second device based on thefirst check result and the second check result, whether a bit errorexists in the to-be-detected section includes: if the second devicedetermines that the first check result is the same as the second checkresult, determining that no bit error exists in the to-be-detectedsection; or if the second device determines that the first check resultis different from the second check result, determining that a bit errorexists in the to-be-detected section.

In a possible design, that the second device deletes the first checkresult from the end block, to obtain an updated end block includes: whena quantity of bytes occupied by the first check result is greater thanor equal to a quantity of target bytes, moving, by the second device,the end byte into a bit block before the end block based on the quantityof bytes occupied by the first check result, adding a new first bitblock to the bit block stream, and using the bit block in which the endbyte is located after being moved as an updated end block; or when aquantity of bytes occupied by the first check result is less than thequantity of target bytes, forward moving, by the second device based onthe quantity of bytes occupied by the first check result, the end byteby the quantity of bytes occupied by the first check result, and using abit block in which the end byte is located after being moved as anupdated end block, where the quantity of target bytes is 1 plus aquantity of bytes located before the end byte in the end block.Therefore, by using the method provided in this embodiment of thisapplication, implementation is simple and convenient.

According to a fifth aspect, a bit block stream bit error detectiondevice is provided, including a processor and a transceiver, where thetransceiver is configured to send a bit block stream, and the processoris configured to complete the foregoing method according to the firstaspect or any possible implementation of the first aspect based on thebit block stream sent by the transceiver.

According to a sixth aspect, a bit block stream bit error detectiondevice is provided, including a processor and a transceiver, where thetransceiver is configured to receive a bit block stream, and theprocessor is configured to complete the foregoing method according tothe second aspect or any possible implementation of the second aspectbased on the bit block stream received by the transceiver.

According to a seventh aspect, a bit block stream bit error detectiondevice is provided, including a processor and a transceiver, where thetransceiver is configured to send a bit block stream, and the processoris configured to complete the foregoing method according to the firstaspect or any possible implementation of the first aspect based on thebit block stream sent by the transceiver.

According to an eighth aspect, a bit block stream bit error detectiondevice is provided, including a processor and a transceiver, where thetransceiver is configured to receive a bit block stream, and theprocessor is configured to complete the foregoing method according tothe second aspect or any possible implementation of the second aspectbased on the bit block stream received by the transceiver.

An embodiment of this application provides a new device for transferringan Mi/M2 bit block stream, where a bit error detection unit, which isalso referred to as a bit error rate (Bit error ratio, BER) unit, a BERfor short, is newly added to the device. The unit is configured tocalculate a check result and detect a bit error. A PE device includes auAdpt, an L1.5 switch, an nAdpt, and a BER. One end of the PE device isconnected to user equipment, an interface is a UNI, the other end isconnected to a network device, and an interface is an NNI. A P deviceincludes a uAdpt, an L1.5 switch, an nAdpt, and a BER, both ends of theP device are connected to a network device, and an interface is an NNI,as shown in FIG. 23(a) and FIG. 23(b).

An embodiment of this application further provides a packet bearerproduct, for example, an IPRAN or PTN device for which an X-Echaracteristic is to be provided as planned. FIG. 24 shows the packetbearer product provided in this application, and an interface boardherein may be an interface card of a box-type device or an interfacechip of a line card of frame-shaped equipment.

Alternatively, an embodiment of this application further provides apacket bearer product. As shown in FIG. 25, this application provides anew chip, such as an SDxxxx, that enables a BER to be built in the chip;or a field-programmable gate array (Field-Programmable Gate Array, FPGA)or a network processor (Network Processor, NP) is added between anexisting interface chip such as an SDyyyy and a main control switchboard, to implement a function of the BER by using the FPGA or the NP.

According to a ninth aspect, this application provides acomputer-readable storage medium, where the computer-readable storagemedium stores an instruction, and when running on a computer, theinstruction enables the computer to perform the foregoing methodaccording to the first aspect or any possible design of the firstaspect.

According to a tenth aspect, this application further provides acomputer program product including an instruction, where when running ona computer, the instruction enables the computer to perform theforegoing method according to the first aspect or any possible design ofthe first aspect.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram of a code type definition of 64/66 bitencoding according to an embodiment of this application;

FIG. 2 is a schematic diagram of a code type definition of an idle blockaccording to an embodiment of this application;

FIG. 3(a) is a schematic structural diagram 1 of a PE device accordingto an embodiment of this application;

FIG. 3(b) is a schematic structural diagram 1 of a P device according toan embodiment of this application;

FIG. 4 is a schematic diagram of networking and forwarding using an X-Etechnology according to an embodiment of this application;

FIG. 5 is a schematic diagram of a basic idea of BIP-8 according to anembodiment of this application;

FIG. 6 shows a bit block stream bit error detection method 1 accordingto an embodiment of this application;

FIG. 7 is a schematic diagram of a position and a code type definitionof a second boundary bit block according to an embodiment of thisapplication;

FIG. 8 is a schematic diagram of inserting a first bit block accordingto an embodiment of this application;

FIG. 9 is a schematic diagram of a basic idea of 8BIP-8 according to anembodiment of this application;

FIG. 10 is a schematic diagram of a basic idea of 16BIP-4 according toan embodiment of this application;

FIG. 11(a) is a schematic diagram of a basic idea of flexBIP-8 accordingto an embodiment of this application;

FIG. 11(b) is a schematic diagram of a basic idea of flexBIP-9 accordingto an embodiment of this application;

FIG. 12 shows a bit block stream bit error detection method 2 accordingto an embodiment of this application;

FIG. 13 shows a bit block stream bit error detection method 3 accordingto an embodiment of this application;

FIG. 14 is a schematic diagram of a 64/66 bit stream according to anembodiment of this application;

FIG. 15 is a schematic diagram of a code type definition of a pure datablock D according to an embodiment of this application;

FIG. 16 is a schematic diagram of a code type definition of a startblock according to an embodiment of this application;

FIG. 17 is a schematic diagram of a code type definition of an end blockaccording to an embodiment of this application;

FIG. 18 is a schematic diagram of storing, by a first device, a firstcheck result in an end block according to an embodiment of thisapplication;

FIG. 19 is a schematic diagram of calculating, by a first device, afirst check result B by using CRC-8 or BIP-8, and inserting the firstcheck result B into an end block according to an embodiment of thisapplication;

FIG. 20 is a schematic diagram of inserting, by a first device, a firstcheck result B into a newly added bit block before an end blockaccording to an embodiment of this application;

FIG. 21 shows a bit block stream bit error detection method 4 accordingto an embodiment of this application;

FIG. 22 is a schematic diagram of deleting, by a second device, a firstcheck result B from an end block according to an embodiment of thisapplication;

FIG. 23(a) is a schematic structural diagram 2 of a PE device accordingto an embodiment of this application;

FIG. 23(b) is a schematic structural diagram 2 of a P device accordingto an embodiment of this application;

FIG. 24 is a schematic structural diagram 1 of a packet bearer productaccording to an embodiment of this application;

FIG. 25 is a schematic structural diagram 2 of a packet bearer productaccording to an embodiment of this application;

FIG. 26 is a schematic diagram of bit error detection in which a path ofa to-be-checked bit block stream is an end-to-end path according to anembodiment of this application;

FIG. 27(a) is a schematic diagram 1 of bit error detection in which apath of a to-be-checked bit block stream is a non-end-to-end pathaccording to an embodiment of this application;

FIG. 27(b) is a schematic diagram 2 of bit error detection in which apath of a to-be-checked bit block stream is a non-end-to-end pathaccording to an embodiment of this application;

FIG. 28 is a schematic structural diagram 1 of a bit block stream biterror detection device according to an embodiment of this application;

FIG. 29 is a schematic structural diagram 2 of a bit block stream biterror detection device according to an embodiment of this application;

FIG. 30 is a schematic structural diagram 3 of a bit block stream biterror detection device according to an embodiment of this application;and

FIG. 31 is a schematic structural diagram 4 of a bit block stream biterror detection device according to an embodiment of this application.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

The following describes the embodiments of this application withreference to accompanying drawings.

A bit block mentioned in the embodiments of this application is an M1/M2bit block (Bit block), and M1/M2 bit represents an encoding manner,where M1 indicates a quantity of payload bits in each bit block, M2indicates a total quantity of bits in each bit block, M2−M1 indicates aquantity of synchronization header bits at a header of each bit block,M1 and M2 are positive integers, and M2 >M1.

It is the M1/M2 bit block stream that is transferred on an Ethernetphysical layer link. For example, 1 G Ethernet uses 8/10 bit encoding,and it is an 8/10 bit block stream that is transferred on a 1 GEphysical layer link; 10GE/40 GE/100 GE uses 64/66 bit encoding, and itis a 64/66 bit block stream that is transferred on a 10 GE/40 GE/100 GEphysical layer link. With the development of Ethernet technologies inthe future, other encoding manners may appear, for example, 128/130 bitencoding, 256/258 bit encoding, and the like. For ease of description,the M1/M2 bit block stream is used in all the embodiments of thisapplication.

In an L1.5 switching M1/M2 bit block stream, different types of bitblocks exist, and are clearly defined in the standard. The followinguses a code type definition of 64/66 bit encoding as an example fordescription, as shown in FIG. 1, in which two bits “10” or “01” at aheader are synchronization header bits of a 64/66 bit block, and 64 bitsafter the synchronization header bits are used to carry payload data ora protocol. There are 16 code type definitions in FIG. 1. Each rowrepresents a code type definition of a bit block, where D0 to D7represent data bytes, C0 to C7 represent control bytes, So represents astart byte, T0 to T7 represent end bytes, row 2 corresponds to a codetype definition of an idle block (IDLE Block), and the idle block may berepresented by /I/, which is specifically shown in FIG. 2. Row 7corresponds to a code type definition of a start block, the start blockmay be represented by /s/, rows 9 to 16 respectively correspond to codetype definitions of eight end blocks, and the eight end blocks may beuniformly represented by /T/.

Further, in an X-E technical hierarchy, devices shown in FIG. 3(a) andFIG. 3(b) are used to transfer the Mi/M2 bit block stream. Specifically,as shown in FIG. 3(a) and FIG. 3(b), a PE device and a P device areincluded. The PE device represents a provider edge device, one end ofthe PE device is connected to user equipment, an interface is a userside interface (User network interface, UNI), the other end is connectedto a network device, and an interface is an NNI. The P device representsa network device, both ends of the P device are connected to a networkdevice, and an interface is a network to network interface (Network toNetwork interface, NNI) or an interface between devices in a network.

FIG. 3(a) is used as an example. A client signal adaptation unit (uAdpt)represents a user side processing unit of the X-E technical hierarchy,and is configured to access a user service signal, and implement codetype conversion and rate adaptation. A network signal adaptation unit(nAdpt) represents a network side processing unit of the X-E technicalhierarchy, and is configured to send a service signal in a device to anetwork side, and complete corresponding function processing; or receivea network side service signal and transmit the signal to anotherprocessing unit in the device. An L1.5 switch or an X-Ethernet switch,that is, an X-Ethernet relay (that is, forwarding by an intermediatenode), is embodied as a switching unit.

FIG. 4 is a schematic diagram of networking and forwarding using an X-Etechnology. A path shown in FIG. 4 is an X-E end-to-end forwarding path.

In addition, the following briefly describes two common check algorithmsused in the embodiments of this application.

(1) BIP-x: BIP-based algorithm, a basic idea of which is dividing ato-be-checked signal into X check blocks. For example, SDH uses BIP-16,BIP-8, and BIP-2, and OTN uses BIP-8.

For example, referring to FIG. 5, a generation process of an 8-bitmonitoring code shown in BIP-8 may be briefly described as follows:dividing all to-be-checked bits of a bit stream into a series of 8-bitsequence code groups, with eight bits for each group. A BIP-8 code isused as the first column, the first 8-bit sequence is used as the secondcolumn, and so on, forming a monitoring matrix. Then, first bits of allthe 8-bit sequence code groups and a first bit of the BIP-8 code form afirst monitoring code group (the first row of the matrix), second bitsof all the 8-bit sequence code groups and a second bit of the BIP-8 codeform a second monitoring code group (the second row of the matrix), andso on. Finally, the first bit of the BIP-8 code provides an even paritycheck for the first monitoring code group (that is, to keep a quantityof ones in the monitoring code group even), the second bit of the BIP-8code provides an even parity check for the second monitoring code group,and so on. It should be known that, an odd parity check mayalternatively be used herein.

(2) CRC-x: CRC-based algorithm, where standardized CRC algorithmsinclude CRC-4, CRC-8, CRC-16, CRC-32, and the like. An X-bit cycliccheck is used for a to-be-checked signal, CRC-32 is used for an Ethernetframe or packet, and a CRC-32 result is stored in the last FCS field(four bytes) of the frame or the packet.

Referring to FIG. 6, an embodiment of this application provides a bitblock stream bit error detection method, to resolve problems ofrelatively high implementation difficulty and relatively low bearerefficiency of a bit error detection method in an M/N bit block switchingscenario. The method includes the following steps.

Step 600: Send a first boundary bit block, where the first boundary bitblock is used to distinguish N bit blocks to be subsequently sent, and Nis a positive integer.

Step 610: Sequentially send an Ith bit block, where I is an integergreater than or equal to 1 and less than or equal to N.

Step 620: Determine a first parity check result and a second paritycheck result, where a check object of the first parity check resultincludes m consecutive bits of each bit block in the N bit blocks, acheck object of the second parity check result includes n consecutivebits of each bit block in the N bit blocks, and at least one of m and nis greater than or equal to 2.

Step 630: Send a second boundary bit block, the first parity checkresult, and the second parity check result, where the second boundarybit block is used to distinguish the N bit blocks that have been sent.

It should be understood that, when a path of a to-be-checked bit blockstream is from a bit block transmit end to a bit block receive end, orwhen a path of the to-be-checked bit block stream is from a bit blocktransmit end to any intermediate device before a bit block receive end,steps in FIG. 6 may be performed by the bit block transmit end. When thepath of the to-be-checked bit block stream is from the bit blocktransmit end to the bit block receive end, the path of the to-be-checkedbit block stream is an end-to-end path. When the path of theto-be-checked bit block stream is from the bit block transmit end to anyintermediate device before the bit block receive end, the path of theto-be-checked bit block stream is a path with one end unconnected. Thebit block transmit end is referred to as a transmitting devicethroughout this application.

Therefore, this embodiment of this application can not only be used toperform bit error detection on an end-to-end path, but can also be usedto perform bit error detection on a non-end-to-end path, for example, aplanned reserved path, a protection path of a 1:1 connection protectiongroup, or a path for another special purpose.

When the path of the to-be-checked bit block stream is from a firstintermediate device after the bit block transmit end to a secondintermediate device before the bit block receive end, the steps in FIG.6 may be performed by the first intermediate device. The path of theto-be-checked bit block stream is a path with both ends unconnected.

For step 600, step 610, and step 630, this embodiment of thisapplication provides the following two possible implementations:

A first possible implementation: sending the first boundary bit block toa first device; sequentially sending the Ith bit block to the firstdevice; and sending the second boundary bit block, the first paritycheck result, and the second parity check result to the first device.

Therefore, in the foregoing implementation, the first parity checkresult, the second parity check result, the two boundary bit blocks, andthe N bit blocks between the two boundary bit blocks are sent togetherto the first device. When the path of the to-be-checked bit block streamis from the bit block transmit end to the bit block receive end, thefirst device herein may be the bit block receive end; or when the pathof the to-be-checked bit block stream is from the bit block transmit endto any intermediate device before the bit block receive end, or when thepath of the to-be-checked bit block stream is from the firstintermediate device after the bit block transmit end to the secondintermediate device before the bit block receive end, the first deviceherein may also be referred to as an intermediate device.

A second possible implementation: sending the first boundary bit blockto a first device; sequentially sending the Ith bit block to the firstdevice; and sending the second boundary bit block to the first device,and sending the first parity check result and the second parity checkresult to a second device.

It should be known that the second device herein may be an SDNcontroller, or any device that has a function of determining a bit errorin bit stream transmission.

In addition, the two manners may be used herein at the same time. Thatis, the first parity check result and the second parity check result aresent not only to the first device but also to the second device.

Further, it should be understood that, the second boundary bit block issent at a first moment, and the first parity check result and the secondparity check result are sent at a second moment, where the first momentis earlier than the second moment, or the first moment is later than thesecond moment, or the first moment is the same as the second moment.

The check object of the first parity check result may be m consecutivebits of each bit block in the N bit blocks, and the check object of thesecond parity check result may be n consecutive bits of each bit blockin the N bit blocks. In a possible implementation, in addition toincluding m consecutive bits of each bit block in the N bit blocks, thecheck object of the first parity check result may further include mconsecutive bits of the first boundary bit block, and may furtherinclude m consecutive bits of the second boundary bit block. Likewise,in addition to including n consecutive bits of each bit block in the Nbit blocks, the check object of the second parity check result mayfurther include n consecutive bits of the first boundary bit block, andmay further include n consecutive bits of the second boundary bit block.

In a possible implementation, the first parity check result and thesecond parity check result may be stored in the second boundary bitblock. Therefore, assuming that every N bit blocks in a bit block streamform one group, an i^(th) boundary bit block stores a first parity checkresult and a second parity check result that correspond to N bit blocksin an i^(th) group, and an (i+1)^(th) boundary bit block stores a firstparity check result and a second parity check result that correspond toN bit blocks in an (i+i)^(th) group, where the N bit blocks in the(i+1)^(th) group are bit blocks between the i^(th) boundary bit blockand the (i+1)^(th) boundary bit block, and i is a positive integer.

It should be understood that the boundary bit block mentioned in thisapplication may be a newly inserted bit block. When a new boundary bitblock is inserted, a first bit block may be deleted, where the first bitblock is a bit block that may be inserted into the N bit blocks ordeleted from the N bit blocks in a transmission process of the N bitblocks. For example, for a 64/66 bit block stream, the first bit blockmay be an idle block.

In an optional embodiment, as shown in FIG. 7, a 64/66 bit block streamis used as an example. After the first parity check result and thesecond parity check result are determined, the second boundary bit blockcorresponds to a bit block code type definition in row 8 in FIG. 1. Tobe specific, a type of the bit block is 0x4B, code 0 of the bit block is0x06, the first parity check result and the second parity check resultare stored in three data fields of the bit block, and unoccupied datafield bits are padded with binary zeros. Therefore, after the secondboundary bit block is inserted into the N bit blocks, an idle block maybe deleted, to reduce impact on user bandwidth.

Considering that an M1/M2 bit block stream passes through anasynchronous node (which means that a receive block may not be fullysynchronized with a node clock and a transmit clock) in the transmissionprocess, a first bit block is usually inserted or deleted, to eliminatea frequency effect. For example, a 64/66 bit block stream is implementedby inserting or deleting an idle block, as shown in FIG. 8. Therefore,when the first parity check result and the second parity check resultare determined in step 620, if an existing BIP-x algorithm is used, thefirst parity check result and the second parity check result may beaffected by insertion or deletion of the first bit block in thetransmission process.

In this embodiment of this application, the first parity check resultand the second parity check result are calculated based on a presetcheck algorithm, where the preset check algorithm is used to keep thefirst parity check result and the second parity check result unchangedwhen the first bit block is added to or removed from the N bit blocks.

Specifically, to ensure that the first parity check result and thesecond parity check result can tolerate one or more first bit blocks(for example, IDLE Blocks) that are inserted or deleted in thetransmission process, and that a bit error occurring in the first bitblock can also be detected, existing BIP algorithms are improved in thisapplication, and may include but are not limited to the following twoalgorithms.

Algorithm 1: The preset check algorithm is an xBIP-y algorithm, where xindicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y ≥2.

Every x consecutive bits of each bit block are sequentially recordedinto a first monitoring section to a y^(th) monitoring section from afirst payload bit in N bit blocks; and a 1-bit monitoring code isdetermined for each monitoring section by using an odd parity check oran even parity check, to obtain a y-bit monitoring code, where the y-bitmonitoring code includes the first parity check result and the secondparity check result.

It should be understood that when the first parity check result and thesecond parity check result are calculated, synchronization header bitsin each bit block are not included.

In an optional embodiment, as shown in FIG. 9, the existing BIP-xalgorithm may be considered as a special case (that is, a scenario inwhich x=1) of the xBIP-y algorithm. FIG. 9 is a schematic diagram ofusing an 8BIP-8 algorithm for a 64/66 bit block. B0 to B7 are eightmonitoring codes (also referred to as check codes) included in the used8BIP-8 algorithm, where each monitoring code corresponds to onemonitoring section, to provide an odd parity check or an even paritycheck for bits included in a corresponding monitoring section. Eachmonitoring section corresponds to eight consecutive bits of each bitblock. For example, a first monitoring section corresponds to a firstpayload bit to an eighth payload bit of each bit block, a secondmonitoring section corresponds to a ninth payload bit to a sixteenthpayload bit of each bit block, . . . , and an eighth monitoring sectioncorresponds to a fifty-seventh payload bit to a sixty-fourth payload bitof each bit block. Specifically, a first byte of the inserted idle blockis oxie, and other bytes are zeros. The first byte of the idle blockenters the first monitoring section of 8BIP-8, and the other bytes enterthe second to the eighth monitoring sections. oxie has a total of fourbinary ones, and other fields are zeros, and have zero binary ones.Therefore, no matter how many idle blocks are inserted or deleted in thetransmission process, a check result of B0 to B7 is not affected.

In an optional embodiment, as shown in FIG. 10, FIG. 10 is a schematicdiagram of using a 16BIP-4 algorithm for a 64/66 bit block. B0 to B3 arefour monitoring codes (also referred to as check codes) included in theused 16BIP-4 algorithm, where each monitoring code corresponds to onemonitoring section, to provide an odd parity check or an even paritycheck for bits included in a corresponding monitoring section. Eachmonitoring section corresponds to 16 consecutive bits of each bit block.For example, a first monitoring section corresponds to a first payloadbit to a sixteenth payload bit of each bit block, a second monitoringsection corresponds to a seventeenth payload bit to a thirty-secondpayload bit of each bit block, a third monitoring section corresponds toa thirty-third payload bit to a forty-eighth payload bit of each bitblock, and a fourth monitoring section corresponds to a forty-ninthpayload bit to a sixty-fourth payload bit of each bit block.

Algorithm 2: The preset check algorithm is a flexBIP-z algorithm, zindicates a quantity of monitoring sections, not all quantities ofconsecutive bit-interleaved bits corresponding to the monitoringsections are the same, and the quantities of consecutive bit-interleavedbits respectively corresponding to the z monitoring sections are A1, A2,A3, . . . , Az−1, and Az, where A1, A2, A3, . . . , Az−1, and Az, and zare positive integers, and z ≥2.

A1 consecutive bits of each bit block are recorded into a firstmonitoring section from a first payload bit in the N bit blocks, A2consecutive bits after the A1 consecutive bits are recorded into asecond monitoring section, and A3 consecutive bits after the A2consecutive bits are recorded into a third monitoring section, until Azconsecutive bits after Az−1 consecutive bits are recorded into a zthmonitoring section; and a 1-bit monitoring code is determined for eachmonitoring section by using an odd parity check or an even parity check,to obtain a z-bit monitoring code, where the z-bit monitoring codeincludes the first parity check result and the second parity checkresult.

In an optional embodiment, as shown in FIG. 11(a), FIG. 11(a) is aschematic diagram of using a flexBIP-8 algorithm for a 64/66 bit block.B0 to B7 are eight monitoring codes included in the used flexBIP-8algorithm, where each monitoring code corresponds to one monitoringsection, to provide an odd parity check or an even parity check for bitsincluded in a corresponding monitoring section. A first monitoringsection corresponds to a first payload bit to an eighth payload bit ofeach bit block, a second monitoring section corresponds to a ninthpayload bit to an eighteenth payload bit of each bit block, a thirdmonitoring section corresponds to a nineteenth payload bit to atwenty-fourth payload bit of each bit block, a fourth monitoring sectioncorresponds to a twenty-fifth payload bit to a thirty-third payload bitof each bit block, a fifth monitoring section corresponds to athirty-fourth payload bit to a fortieth payload bit of each bit block, asixth monitoring section corresponds to a forty-first payload bit to aforty-eighth payload bit of each bit block, a seventh monitoring sectioncorresponds to a forty-ninth payload bit to a fifty-eighth payload bitof each bit block, and an eighth monitoring section corresponds to afifty-ninth payload bit to a sixty-fourth payload bit of each bit block.

In an optional embodiment, as shown in FIG. 11(b), FIG. 11(b) is aschematic diagram of using a flexBIP-9 algorithm for a 64/66 bit block.B0 to B8 are nine monitoring codes included in the used flexBIP-9algorithm, where each monitoring code corresponds to one monitoringsection, to provide an odd parity check or an even parity check for bitsincluded in a corresponding monitoring section. A first monitoringsection corresponds to a total of seven bits ranging from a firstpayload bit to an eighth payload bit of each bit block, a secondmonitoring section corresponds to a total of seven bits ranging from aninth payload bit to a fifteenth payload bit of each bit block, a thirdmonitoring section corresponds to a total of seven bits ranging from asixteenth payload bit to a twenty-second payload bit of each bit block,a fourth monitoring section corresponds to a total of seven bits rangingfrom a twenty-third payload bit to a twenty-ninth payload bit of eachbit block, a fifth monitoring section corresponds to a total of sevenbits ranging from a thirtieth payload bit to a thirty-sixth payload bitof each bit block, a sixth monitoring section corresponds to a total ofseven bits ranging from a thirty-seventh payload bit to a forty-thirdpayload bit of each bit block, a seventh monitoring section correspondsto a total of seven bits ranging from a forty-fourth payload bit to afiftieth payload bit of each bit block, an eighth monitoring sectioncorresponds to a total of seven bits ranging from a fifty-first payloadbit to a fifty-seventh payload bit of each bit block, and a ninthmonitoring section corresponds to a total of seven bits ranging from afifty-eighth payload bit to a sixty-fourth payload bit of each bitblock.

When the first parity check result and the second parity check resultare determined in step 620, the check object of the first parity checkresult includes the N bit blocks and the first boundary bit block instep 600, and any one of nine consecutive bit groups of each bit blockenters a check area corresponding to the flexBIP-9 algorithm, therebyfinally forming the first parity check result. The check object of thesecond parity check result includes the N bit blocks and the firstboundary bit block in step 600, and any one of the other eight groups,different from the one group selected by the first parity check result,in the nine consecutive bit groups of each bit block enters a check areacorresponding to the flexBIP-9 algorithm, thereby finally forming thesecond parity check result.

When the first parity check result and the second parity check resultare determined in step 620, the check object of the first parity checkresult includes the N bit blocks and the second boundary bit block instep 630, any one of nine consecutive bit groups of each bit blockenters a check area corresponding to the flexBIP-9 algorithm, therebyfinally forming the first parity check result. The check object of thesecond parity check result includes the N bit blocks and the secondboundary bit block in step 630, any one of the other eight groups,different from the one group selected by the first parity check result,in the nine consecutive bit groups of each bit block enters a check areacorresponding to the flexBIP-9 algorithm, thereby finally forming thesecond parity check result.

When a third parity check result and a fourth parity check result aredetermined in the following step 1230, a check object of the thirdparity check result includes T bit blocks and a first boundary bit blockin step 1200, any one of nine consecutive bit groups of each bit blockenters a check area corresponding to the flexBIP-9 algorithm, therebyfinally forming the third parity check result. A check object of thefourth parity check result includes the T bit blocks and the firstboundary bit block in step 600, and any one of the other eight groups,different from the one group selected by the third parity check result,in the nine consecutive bit groups of each bit block enters a check areacorresponding to the flexBIP-9 algorithm, thereby finally forming thefourth parity check result.

When the third parity check result and the fourth parity check resultare determined in step 1230, the check object of the third parity checkresult includes the T bit blocks and a second boundary bit block in step1220, and any one of nine consecutive bit groups of each bit blockenters a check area corresponding to the flexBIP-9 algorithm, therebyfinally forming the third parity check result. The check object of thefourth parity check result includes the T bit blocks and the secondboundary bit block in step 1220, and any one of the other eight groups,different from the one group selected by the third parity check result,in the nine consecutive bit groups of each bit block enters a check areacorresponding to the flexBIP-9 algorithm, thereby finally forming thefourth parity check result.

Specifically, the inserted bit block is an idle block (IDLE Block), afirst byte of the idle block is oxie, and other bytes are zeros. Thefirst byte of the idle block enters the first monitoring section offlexBIP-9, and other bytes are grouped by seven consecutive bits, andenter the second to the ninth monitoring sections. oxie has a total offour binary ones, and other fields are zeros, and have zero binary ones.Therefore, no matter how many idle blocks are inserted or deleted in thetransmission process, a check result of B0 to B8 is not affected.

Specifically, when the inserted bit block is a low power idle block (LPIBlock), a first byte is oxie, other bytes are grouped by seven bits intoeight groups, and each group is 0x6. The first byte of LPI enters thefirst monitoring section of flexBIP-9, and other bytes are grouped byseven consecutive bits, and enter the second to the ninth monitoringsections. oxie has a total of four binary ones, and other 7-bit fieldsare 0x6, and have two binary ones. Therefore, no matter how many LPIblocks are inserted or deleted in the transmission process, the checkresult of B0 to B8 is not affected.

Specifically, when the inserted bit block is an error block (ERRORBlock), a first byte is 0x1e, other bytes are grouped by seven bits intoeight groups, and each group is 0x1e. The first byte of the error blockenters the first monitoring section of flexBIP-9, and other bytes aregrouped by seven consecutive bits, and enter the second to the ninthmonitoring sections. oxie has a total of four binary ones. Therefore, nomatter how many error blocks are inserted or deleted in the transmissionprocess, the check result of B0 to B8 is not affected.

Therefore, it can be learned from the two preset algorithms providedabove that, the y-bit monitoring code obtained by using the algorithm 1may be used as a first check result set; or the z-bit monitoring codeobtained by using the algorithm 2 may be used as the first check resultset. When the first parity check result and the second parity checkresult are being sent, all check results that are obtained, that is, thefirst check result set, may be sent together.

Referring to FIG. 12, an embodiment of this application provides a bitblock stream bit error detection method, to resolve problems ofrelatively high implementation difficulty and relatively low bearerefficiency of a bit error detection method in an M/N bit block switchingscenario. The method includes the following steps:

Step 1200: Receive a first boundary bit block, where the first boundarybit block is used to distinguish T bit blocks to be subsequentlyreceived, and T is a positive integer.

Step 1210: Sequentially receive an I^(th) bit block, where I is aninteger greater than or equal to 1 and less than or equal to T.

Step 1220: Receive a second boundary bit block, where the secondboundary bit block is used to distinguish the T bit blocks that havealready been received.

Step 1230: Determine a third parity check result and a fourth paritycheck result, where a check object of the third parity check resultincludes m consecutive bits of each bit block in the T bit blocks, acheck object of the fourth parity check result includes n consecutivebits of each bit block in the T bit blocks, and at least one of m and nis greater than or equal to 2.

Step 1240: When a first parity check result and a second parity checkresult are received, determine, based on the first parity check resultand the third parity check result, and the second parity check resultand the fourth parity check result, whether a bit error exists in the Tbit blocks, where a check object of the first parity check resultincludes m consecutive bits of each bit block in N bit blocks, a checkobject of the second parity check result includes n consecutive bits ofeach bit block in the N bit blocks, and N indicates a quantity of bitblocks between the first boundary bit block and the second boundary bitblock when the first parity check result and the second parity checkresult are determined.

It should be understood that, when a path of a to-be-checked bit blockstream is from a bit block transmit end to a bit block receive end,steps in FIG. 12 may be performed by the bit block receive end; or whenthe path of the to-be-checked bit block stream is from the bit blocktransmit end to any intermediate device before the bit block receiveend, or when the path of the to-be-checked bit block stream is from thebit block transmit end to the bit block receive end, the steps in FIG.12 may be performed by an intermediate device. The bit block receive endis referred to as a receiving device throughout this application.

It should be known that the N bit blocks herein are bit blocks betweenthe first boundary bit block and the second boundary bit block when atransmitting device determines the first parity check result and thesecond parity check result.

In an optional embodiment, after sending the first boundary bit block,the transmitting device sequentially sends the N bit blocks, thencalculates the first parity check result and the second parity checkresult based on the N bit blocks, stores the two results into the secondboundary bit block, and sends the second boundary bit block. However,considering that a path from the transmitting device to the receivingdevice needs to pass through an asynchronous node, a first bit block maybe inserted into or deleted from the N bit blocks. After receiving thefirst boundary bit block, the receiving device sequentially receives theT bit blocks, and then three cases may occur: N=T, or N>T (which meansthat a first bit block is inserted into the N bit blocks), or N<T (whichmeans that a first bit block is deleted from the N bit blocks).

In a possible implementation, when a first parity check result and asecond parity check result are not received, the third parity checkresult and the fourth parity check result are sent to a second device,where the second device stores the first parity check result and thesecond parity check result. It should be known that the second deviceherein may be an SDN controller, or any device that has a function ofdetermining a bit error in bit stream transmission. In addition, whenthe first parity check result and the second parity check result arereceived, the third parity check result and the fourth parity checkresult may also be sent to the second device. Therefore, the seconddevice may receive the first parity check result and the second paritycheck result that are sent by the transmitting device, and the thirdparity check result and the fourth parity check result that are sent bythe receiving device, and the second device determines, based on the twosets of results, whether a bit error exists in a transmission process ofthe bit block stream.

In a possible implementation, the second boundary bit block is receivedat a first moment, and the first parity check result and the secondparity check result are received at a second moment, where the firstmoment is earlier than the second moment, or the first moment is laterthan the second moment, or the first moment is the same as the secondmoment.

The check object of the third parity check result may be m consecutivebits of each bit block in the T bit blocks, the check object of thefourth parity check result may be n consecutive bits of each bit blockin the T bit blocks, the check object of the first parity check resultmay be m consecutive bits of each bit block in the N bit blocks, and thecheck object of the second parity check result may be n consecutive bitsof each bit block in the N bit blocks. In a possible implementation, inaddition to including m consecutive bits of each bit block in the T bitblocks, the check object of the third parity check result may furtherinclude m consecutive bits of the first boundary bit block, and mayfurther include m consecutive bits of the second boundary bit block.Likewise, in addition to including n consecutive bits of each bit blockof the T bit blocks, the check object of the fourth parity check resultmay further include n consecutive bits of the first boundary bit block,and may further include n consecutive bits of the second boundary bitblock. In addition to including m consecutive bits of each bit block inthe N bit blocks, the check object of the first parity check result mayfurther include m consecutive bits of the first boundary bit block, andmay further include m consecutive bits of the second boundary bit block.Likewise, in addition to including n consecutive bits of each bit blockin the N bit blocks, the check object of the second parity check resultmay further include n consecutive bits of the first boundary bit block,and may further include n consecutive bits of the second boundary bitblock.

When the check object of the first parity check result includes mconsecutive bits of the first boundary bit block, the check object ofthe third parity check result also needs to include m consecutive bitsof the first boundary bit block; when the check object of the firstparity check result includes m consecutive bits of the second boundarybit block, the check object of the third parity check result also needsto include m consecutive bits of the second boundary bit block; when thecheck object of the second parity check result includes n consecutivebits of the first boundary bit block, the check object of the fourthparity check result also needs to include n consecutive bits of thefirst boundary bit block; and when the check object of the second paritycheck result includes n consecutive bits of the second boundary bitblock, the check object of the fourth parity check result also needs toinclude n consecutive bits of the second boundary bit block.

In a possible implementation, the first parity check result and thesecond parity check result are stored in the second boundary bit block.

In a possible implementation, a specific method for determining, by thereceiving device based on the first parity check result and the thirdparity check result, and the second parity check result and the fourthparity check result, whether a bit error exists in the T bit blocks is:if it is determined that the first parity check result is the same asthe third parity check result, and the second parity check result is thesame as the fourth parity check result, determining that no bit errorexists in the T bit blocks; or if it is determined that the first paritycheck result is different from the third parity check result, and/or thesecond parity check result is different from the fourth parity checkresult, determining that a bit error exists in the T bit blocks.

In addition, it should be understood that a preset algorithm used whenthe receiving device determines the third parity check result and thefourth parity check result is the same as a preset algorithm used whenthe transmitting device determines the first parity check result and thesecond parity check result. Same parts are not described again.

In a possible implementation, if the receiving device receives a firstcheck result set, and the first check result set is calculated based onan xBIP-y algorithm, a y-bit monitoring code included in the first checkresult set includes the first parity check result and the second paritycheck result. Then, the receiving device needs to determine a secondcheck result set, where the second parity check result set is calculatedbased on the xBIP-y algorithm, and a y-bit monitoring code included inthe second check result set includes the third parity check result andthe fourth parity check result. Further, the receiving devicedetermines, based on the first check result set and the second checkresult set, whether a bit error exists in the T bit blocks.

In a possible implementation, if the receiving device receives a firstcheck result set, and the first check result set is calculated based ona flexBIP-z algorithm, a z-bit monitoring code included in the firstcheck result set includes the first parity check result and the secondparity check result. Then, the receiving device needs to determine asecond check result set, where the second check result set is calculatedbased on the flexBIP-z algorithm, and a z-bit monitoring code includedin the second check result set includes the third parity check resultand the fourth parity check result. Further, the receiving devicedetermines, based on the first check result set and the second checkresult set, whether a bit error exists in the T bit blocks.

Specifically, that the receiving device determines, based on the firstcheck result set and the second check result set, whether a bit errorexists in the T bit blocks includes the following two possible cases.

(1) if it is determined that the first check result set is the same asthe second check result set, determining that no bit error exists in theT bit blocks; or

(2) if it is determined that the first check result set is differentfrom the second check result set, determining that a bit error exists inthe T bit blocks.

By using the method provided in this embodiment of this application,error or bit error detection on a network path of an M/N bit block canbe fully implemented, with no impact on a user service; bearerefficiency is 100%, and a bit block that is inserted or deleted due tosynchronization in a transfer process can be tolerated; in addition, adetection period (that is, a quantity of bit blocks between the twoboundary bit blocks) and detection precision (that is, a presetalgorithm) can be dynamically configured according to a requirement. Inaddition, the detection method can not only be used for a to-be-checkedbit block stream whose path is an end-to-end path, but can also be usedfor a to-be-checked bit block stream whose path is a non-end-to-endpath.

Referring to FIG. 13, an embodiment of this application provides a bitblock stream bit error detection method, to resolve problems ofrelatively high implementation difficulty and relatively low bearerefficiency of a bit error detection method in an M/N bit block switchingscenario. The method includes the following steps.

Step 1300: A first device determines a to-be-detected section based on astart byte in a start block in a bit block stream and an end byte in anend block corresponding to the start block.

As shown in FIG. 14, for a 64/66 bit stream, a user service starts witha start block marker /S/, and ends with an end block marker /T/, and Dtherebetween is a pure data block, which is specifically shown in FIG.15. As shown in FIG. 1, row 7 corresponds to a code type definition ofthe start block, and So represents a start byte, which is specificallyshown in FIG. 16. Rows 9 to 16 respectively correspond to eight codetype definitions of the end block, and T0 to T7 represent end bytes,which are specifically shown in FIG. 17. For example, the end blockincludes To, and then the to-be-detected section includes bytes betweenS0 and T0.

Step 1310: The first device calculates a first check result based on theto-be-detected section.

An algorithm used when the first device calculates the first checkresult may be CRC-x or BIP-x, the first check result is recorded as B,and B may be one or more bytes.

Step 1320: The first device sends the first check result and the bitblock stream.

For step 1320, that the first device sends the first check result andthe bit block stream may specifically include the following two possibleimplementations:

In a first possible implementation, the first device sends the firstcheck result and the bit block stream to a second device.

In a second possible implementation, the first device sends the firstcheck result to a third device, and sends the bit block stream to thesecond device.

It should be known that the first device herein is a bit block transmitend, the second device is a bit block receive end, and the third deviceis an SDN controller, or any device that has a function of determining abit error in bit stream transmission.

In a possible implementation, before the first device sends the firstcheck result and the bit block stream to the second device, the firstdevice needs to store the calculated first check result. There are thefollowing two possible storage manners.

Storage manner 1: The first device stores the first check result intothe end block, to obtain an updated end block.

As shown in FIG. 18, that the first device stores the first check resultinto the end block specifically includes the following two scenarios.

Scenario 1: When a quantity of bytes occupied by the first check resultis greater than or equal to a quantity of target bytes, the first devicestores the first check result at a position before an end byte in theend block, moves the end byte into a newly added block after the endblock based on the quantity of bytes occupied by the first check result,deletes any first bit block in the bit block stream, and uses the newlyadded block in which the end byte is located after being moved as anupdated end block. The quantity of target bytes is 1 plus a quantity ofbytes located after the end byte in the end block.

Scenario 2: When a quantity of bytes occupied by the first check resultis less than the quantity of target bytes, the first device stores thefirst check result at a position before the end byte in the end block,backward moves, based on the quantity of bytes occupied by the firstcheck result, the end byte by the quantity of bytes occupied by thefirst check result, and uses a bit block in which the end byte islocated after being moved as an updated end block. The quantity oftarget bytes is 1 plus a quantity of bytes located after the end byte inthe end block.

In an optional embodiment, as shown in FIG. 19, when the first deviceuses CRC-8 or BIP-8 to calculate the first check result B, B occupiesonly one byte.

When B is not inserted into the end block, and if the end block is D0 D1D2 D3 D4 D5 D6 T7, the quantity of target bytes is 1; and after B isinserted, the end block is updated to D0 D1 D2 D3 D4 D5 D6 B, then a newblock is added, and an updated end block is T0 C1 C2 C3 C4 C5 C6 C7.

When B is not inserted into the end block, and if the end block is T0 C1C2 C3 C4 C5 C6 C7, the quantity of target bytes is 8; and after B isinserted, an updated end block is B T1 C1 C2 C3 C4 C5 C6. Likewise, whenB is not inserted into the end block, and if end bytes included in theend block are T1 to T6 respectively, after B is inserted, the end bytesare correspondingly updated to T2 to T7.

Storage manner 2: The first device stores the first check result into acheck result storage block, and deletes any first bit block in the bitblock stream, where the check result storage block is a newly addedblock located before the end block, and the first bit block is a bitblock that may be inserted into the bit block stream or deleted from thebit block stream in a transmission process of the bit block stream.

For example, a separate data block is allocated before the end block andnext to the end block, to store the first check result B that iscalculated by using CRC-x or BIP-x, where a type of the data block is D0D1 D2 D3 D4 D5 D6 D7, which corresponds to a code type definition in rowi in FIG. 1. D0 to D7 are used to store the calculated result B, andwhen B is inserted, an idle block (a block with an identifier /I/) aftera block /T/ is deleted, to reduce impact on user bandwidth. As shown inFIG. 20, B occupies one separate block, and one idle block after /T/ isdeleted.

Referring to FIG. 2i , an embodiment of this application provides a bitblock stream bit error detection method, to resolve problems ofrelatively high implementation difficulty and relatively low bearerefficiency of a bit error detection method in an M/N bit block switchingscenario. The method includes the following steps.

Step 2100: A second device determines a to-be-detected section based ona start byte in a start block in a bit block stream and an end byte inan end block corresponding to the start block.

For step 2100, that a second device determines a to-be-detected sectionbased on a start byte in a start block in a bit block stream and an endbyte in an end block corresponding to the start block includes thefollowing three specific cases.

Case 1: If the second device receives a first check result, and thefirst check result is stored in the end block, the second device deletesa first check result from the end block, to obtain an updated end block,and uses bytes between the start byte in the start block and an end bytein the updated end block as the to-be-detected section.

Case 2: If the second device receives the first check result, and thefirst check result is stored in a check result storage block, the seconddevice deletes the check result storage block from the bit block stream,to obtain an updated bit block stream, and uses bytes between the startbyte in the start block in the updated bit block stream and the end bytein the end block as the to-be-detected section, where the check resultstorage block is located before the end block.

In the foregoing two cases, the first check result is included in thebytes between the start byte in the start block and the end byte in theend block. Therefore, the first check result needs to be first deleted,and a remaining part is used as the to-be-detected detection.

Case 3: If the second device does not receive the first check result,the second device uses bytes between the start byte in the start blockin the bit block stream and the end byte in the end block as theto-be-detected section.

In this case, the first check result is not included in the bytesbetween the start byte in the start block and the end byte in the endblock, so that the bytes can be directly used as the to-be-detectedsection.

Specifically, in a possible implementation, if the second device doesnot receive the first check result, the second device sends the secondcheck result to a third device, and the third device stores the firstcheck result. The third device is an SDN controller, or any device thathas a function of determining a bit error in bit stream transmission.

Step 2110: The second device calculates a second check result based onthe to-be-detected section.

Likewise, an algorithm used when the second device calculates the secondcheck result is the same as that used when a first device calculates thefirst check result.

Step 2120: When the second device receives a first check result, thesecond device determines, based on the first check result and the secondcheck result, whether a bit error exists in the to-be-detected section.

Specifically, if the second device determines that the first checkresult is the same as the second check result, the second devicedetermines that no bit error exists in the to-be-detected detection; orif the second device determines that the first check result is differentfrom the second check result, the second device determines that a biterror exists in the to-be-detected section.

Further, that the second device deletes the first check result from theend block, to obtain an updated end block specifically includes thefollowing two scenarios:

Scenario 1: When a quantity of bytes occupied by the first check resultis greater than or equal to a quantity of target bytes, the seconddevice moves the end byte into a bit block before the end block based onthe quantity of bytes occupied by the first check result, adds a newfirst bit block to the bit block stream, and uses the bit block in whichthe end byte is located after being moved as an updated end block. Thequantity of target bytes is 1 plus a quantity of bytes located beforethe end byte in the end block.

Scenario 2: When a quantity of bytes occupied by the first check resultis less than the quantity of target bytes, the first device forwardmoves, based on the quantity of bytes occupied by the first checkresult, the end byte by the quantity of bytes occupied by the firstcheck result, and uses a bit block in which the end byte is locatedafter being moved as an updated end block. The quantity of target bytesis i plus a quantity of bytes located before the end byte in the endblock.

As shown in FIG. 22, when the first device uses CRC-8 or BIP-8 tocalculate a first check result B, B occupies only one byte.

When the end block is B T1 C1 C2 C3 C4 C5 C6, the quantity of targetbytes is 2. After B is deleted, an updated end block is To C1 C2 C3 C4C5 C6 C7. Likewise, if end bytes included in the end block are T2 to T7respectively, after B is deleted, the end bytes are correspondinglyupdated to T1 to T6.

When the end block is T0 C1 C2 C3 C4 C5 C6 C7, a data block next to theend block is D0 D1 D2 D3 D4 D5 D6 B, a quantity of target bytes is i,and after B is deleted, an updated end block is D0 D1 D2 D3 D4 D5 D6 T7.

In addition, if the second device receives the first check result, andthe first check result is stored in the check result storage block, thesecond device deletes the check result storage block from the bit blockstream, to obtain the updated bit block stream, where the check resultstorage block is located before the end block. At the same time, toreduce impact on user bandwidth, a first bit block needs to be addedafter the end block.

By using the method provided in this embodiment of this application,error or bit error detection on a network path of an M/N bit block canbe fully implemented, with little impact on a user service; bearerefficiency is close to bearer efficiency of SDH/OTN, and superior tobearer efficiency of an existing packet detection method; and animplementation procedure is simple, and easy to implement.

An embodiment of this application provides a new device for transferringan M1/M2 bit block stream, where a bit error detection unit, which isalso referred to as a bit error rate (BER) unit, a BER for short, isnewly added to the device. The unit is configured to calculate a checkresult and detect a bit error.

APE device includes a uAdpt, an L1.5 switch, an nAdpt, and a BER. Oneend of the PE device is connected to user equipment, an interface is aUNI, the other end is connected to a network device, and an interface isan NNI. A P device includes a uAdpt, an L1.5 switch, an nAdpt, and aBER, both ends of the P device are connected to a network device, and aninterface is an NNI, as shown in FIG. 23(a) and FIG. 23(b).

An embodiment of this application further provides a packet bearerproduct, for example, an IPRAN or PTN device for which an X-Echaracteristic is to be provided as planned. FIG. 24 shows the packetbearer product provided in this application, and an interface boardherein may be an interface card of a box-type device or an interfacechip of a line card of frame-shaped equipment.

Alternatively, an embodiment of this application further provides apacket bearer product. As shown in FIG. 25, this application provides anew chip, such as an SDxxxx, that enables a BER to be built in the chip;or a field-programmable gate array (FPGA) or a network processor(Network Processor, NP) is added between an existing interface chip suchas an SDyyyy and a main control switch board, to implement a function ofthe BER by using the FPGA or the NP.

The following describes this embodiment of this application withreference to the accompanying drawings.

In an optional embodiment, referring to FIG. 26, a path of ato-be-checked bit block stream is an end-to-end path.

Embodiment 1: The embodiment shown in FIG. 26 is described by using anexample in which a user side interface (UNI) is a iGE interface, anetwork side interface (NNI) is a iooGE interface, three-terminal X-Edevices are XE 1, XE 2, and XE 3, a switching granularity of an L1.5switch and a network side signal stream are a 64/66 bit block stream,and one 8BIP-8 check result is inserted every 1024 blocks on a user sideof the XE 1.

Step 1: 1GE user signals enter the XE 1 device from a UNI side, and auAdpt converts an 8/10 bit block into a 64/66 bit block, which meansthat the uAdpt sequentially assembles eight 1 GE user signals with a2-bit synchronization header removed into one 64-bit string, and thenadds a 2-bit synchronization header to form one 64/66 bit block, therebyfinally forming a 64/66 bit block stream by using the method. A BERcounts a quantity of blocks in the bit block stream from the uAdpt side,inserts a first boundary bit block at a position before the first bitblock, and calculates a first check result set by using an 8BIP-8algorithm. After the quantity of blocks reaches 1024 and the 1024 blocksare used as a first block group, the BER stores the first check resultset into a bit block identified by 4B and 06, and inserts the bit blockafter the 1024th bit block as a second boundary bit block. At the sametime, the BER deletes an idle block from the bit block stream. The bitblock stream processed by the BER enters the L1.5 switch, and thenenters an nAdpt to be sent to a network side.

It should be known that, the BER continues counting the quantity ofblocks, and calculates a first check result set of a second block groupby using the 8BIP-8 algorithm, where a processing method is the same asthat for the first block group. Then, the first check result set of thesecond block group is stored into a bit block identified by 4B and 06,and the bit block is inserted after the 2048^(th) bit block as a thirdboundary bit block. The BER repeats the foregoing process until the bitblock stream ends.

Step 2: The bit block stream sent by the XE1 is transferred to an nAdptof the XE2, where receive clock frequency is slower than system clockfrequency of the XE1, and therefore the nAdpt of the XE2 needs to insertone or more idle blocks when sending the bit block stream to an L1.5switch, to tolerate a transfer rate problem caused by clock frequencynon-synchronization; and then the bit block stream is transferred to thenetwork side XE3.

Step 3: The bit block stream sent by the XE2 is transferred to the XE3,where the bit block stream passes through an nAdpt and an L1.5 switch,and reaches a BER unit on a UNI side; and when receiving the firstboundary bit block, the BER starts to perform 8BIP-8 parity checkcalculation on the bit block stream to be subsequently received, andwhen receiving the second boundary bit block inserted by the XE1, theBER stops calculating, and uses bit blocks between the first boundarybit block and the second boundary bit block as a first block group. TheBER compares a currently calculated second check result set with thefirst check result set stored in the second boundary bit block. If thetwo sets are consistent, the BER determines that no bit error exists; orif the two sets are inconsistent, the BER counts and stores a quantityof bit errors. At the same time, the BER deletes the second boundary bitblock from the bit block stream, and inserts an idle block. After thebit block stream processed by the BER reaches a uAdpt, the uAdpt removestwo synchronization header bits, divides 64 bits into eight 8-bitgroups, adds a 2-bit synchronization header to each of the eight 8-bitgroups, and then sequentially sends the eight 8-bit groups to a UNIlink.

It should be known that the BER continues counting the quantity ofblocks, and calculates a second check result set of the second blockgroup by using the 8BIP-8 algorithm, where the second block group is bitblocks between the second boundary bit block and the third boundary bitblock. When receiving the third boundary bit block inserted by the XE1,the BER stops calculating. A processing method is the same as that forthe first block group. The BER compares the currently calculated secondcheck result set of the second block group with the first check resultset that is of the second block group and that is stored in the thirdboundary bit block. If the two sets are consistent, the BER determinesthat no bit error exists; or if the two sets are inconsistent, the BERcounts and stores a quantity of bit errors. The BER repeats theforegoing process until the bit block stream ends.

Therefore, the user signal enters the XE1, is transferred through theXE2, and flows out of a network from the XE3, so that xBIP-y bit errordetection is fully implemented on an entire end-to-end path, and animplementation is simple. An idle block is added or deleted tocompensate for a block that carries an xBIP-y result, with no impact ona user service, and bearer efficiency is 100%. There is a need to passthrough an asynchronous node in a transfer process, and an idle block isinserted or deleted. The xBIP-y algorithm tolerates such a scenario, andensures an accurate and effective check result.

In addition, the 8BIP-8 algorithm mentioned above may be replaced with aflexBIP-z algorithm by calculation.

The xBIP-y algorithm or the flexBIP-y algorithm is obviously superior toa static and rigid manner of Ethernet, SDH, or OTN that occupies fixedbytes. Because the first bit block is used for compensation, there is noimpact on a user signal. However, for bit error or error detection ofexisting Ethernet, SDH, or OTN, fixed bytes are occupied, and userbandwidth is occupied. In an optional embodiment, referring to FIG.27(a) and FIG. 27(b), a path of a to-be-checked bit block stream is anon-end-to-end path.

It should be noted that, a unit that is located at a start end of a pathshown in FIG. 27(a) and that calculates the first check result set andinserts the first check result set into the second boundary bit block isa BER on an nAdpt unit side, and a unit that is located at a terminationend of the path and that calculates the second check result set anddeletes the second boundary bit block is a BER on an nAdpt unit side.

In addition, no user signal is inserted or extracted on the path shownin FIG. 27(a), that is, the uAdpts at both ends do not need to perform arelated operation.

A unit that is located at a start end of a path shown in FIG. 27(b) andthat calculates the first check result set and inserts the first checkresult set into the second boundary bit block is a BER on a uAdpt unitside, and a unit that is located at a termination end of the path andthat calculates the second check result set and deletes the secondboundary bit block is a BER on an nAdpt unit side.

Moreover, the bit block stream on the path shown in FIG. 27(b) does notflow to an

L1.5 switch and a uAdpt unit at the termination end.

Embodiment 2: The embodiment shown in FIG. 26 is described by using anexample in which a user side interface (UNI) is a iGE interface, anetwork side interface (NNI) is a iooGE interface, three-terminal X-Edevices are XE1, XE2, and XE3, a switching granularity of an L1.5 switchand a network side signal stream are a 64/66 bit block stream, and oneBIP-8 result B1 is inserted into an end block on a user side of the XE1.

Step 1: 1GE user signals enter the XE1 device from a UNI side, and auAdpt converts an 8/10 bit block into a 64/66 bit block, which meansthat the uAdpt sequentially assembles eight 1GE user signals with a2-bit synchronization header removed into one 64-bit string, and thenadds a 2-bit synchronization header to form one 64/66 bit block, therebyfinally forming a 64/66 bit block stream by using the method. A BERidentifies the bit block stream from the uAdpt side, starts to performBIP-8 calculation when receiving a block with a start block identifier/S/, stops calculating when receiving a block with an end blockidentifier /T/, inserts the result B1 before /T/, and modifies a codetype of /T/ at the same time. The bit block stream processed by the BERenters the L1.5 switch, and then enters an nAdpt to be sent to a networkside.

It should be known that, the BER continues identifying the bit blockstream from the uAdpt side, and repeats the foregoing process until thebit block stream ends.

Step 2: The bit block stream sent by the XE1 is transferred to an nAdptof the XE2, where receive clock frequency is slower than system clockfrequency of the XE1, and therefore the nAdpt of the XE2 needs to insertone or more idle blocks when sending the bit block stream to an L1.5switch, to tolerate a transfer rate problem caused by clock frequencynon-synchronization; and then the bit block stream is transferred to XE3on a network side.

Step 3: The bit block stream sent by the XE2 is transferred to the XE3,where the bit block stream passes through an nAdpt and an L1.5 switch,and reaches a BER unit on a UNI side; the BER identifies the bit blockstream, starts to perform BIP-8 calculation when receiving the blockwith the start block identifier /S/, when receiving the block with theend block identifier /T/, keeps calculating until the result B1 is foundin the end block, deletes the result Bi, and modifies the code type of/T/ at the same time. The BER compares a currently calculated result B2with the result B1. If the two results are consistent, the BERdetermines that no bit error exists; or if the two results areinconsistent, the BER counts a quantity of bit errors and stores the biterror. After the bit block stream processed by the BER reaches a uAdpt,the uAdpt removes two synchronization header bits, divides 64 bits intoeight 8-bit groups, adds a 2-bit synchronization header to each of theeight 8-bit groups, and then sequentially sends the eight 8-bit groupsto a UNI link.

In addition, the BIP-8 algorithm mentioned above may be replaced with aCRC-8 algorithm by calculation.

Therefore, the user signal enters the XE1, is transferred through theXE2, and flows out of a network from the XE3, so that CRC or BIP biterror detection is fully implemented on an entire end-to-end path, animplementation is simple, and bearer efficiency is improved incomparison with bearer efficiency of existing Ethernet, close to bearerefficiency of SDH and OTN, but still inferior to bearer efficiency ofthe embodiment i shown in FIG. 26.

Moreover, if the BER in step 1 inserts the result B1 in a separate blockbefore the block /T/, and deletes an idle block after the block /T/, andif the BER in step 3 deletes the separate block, and adds an idle blockafter the block /T/ for compensation, there is no impact on a userservice, and bearer efficiency is 100%.

The bit block stream bit error detection method provided in thisembodiment of this application is a detection manner for a bit blockstream transfer path, is not limited to telecommunication wired bearer,and can be fully applied to a wireless communication, industrial orindustrial communication network.

Based on a same concept, this application further provides a bit blockstream bit error detection device, where the device may be used toimplement the foregoing corresponding method embodiment in FIG. 6.Therefore, for an implementation of the bit block stream bit errordetection device provided in this embodiment of this application, referto an implementation of the method. Same parts are not described again.

Referring to FIG. 28, an embodiment of this application provides a bitblock stream bit error detection device 2800, including: a transceiver2801 and a processor 2802.

The transceiver 2801 is configured to send a first boundary bit block,where the first boundary bit block is used to distinguish N bit blocksto be subsequently sent, and N is a positive integer; and sequentiallysend an Ith bit block, where I is an integer greater than or equal to 1and less than or equal to N.

The processor 2802 is configured to determine a first parity checkresult and a second parity check result, where a check object of thefirst parity check result includes m consecutive bits of each bit blockin the N bit blocks, a check object of the second parity check resultincludes n consecutive bits of each bit block in the N bit blocks, andat least one of m and n is greater than or equal to 2.

The transceiver 2801 is further configured to send a second boundary bitblock, the first parity check result, and the second parity checkresult, where the second boundary bit block is used to distinguish the Nbit blocks that have been sent.

In a possible design, a type of each bit block is an M1/M2 bit block, M1indicates a quantity of payload bits in each bit block, M2 indicates atotal quantity of bits in each bit block, M2−M1 indicates a quantity ofsynchronization header bits at a header of each bit block, M1 and M2 arepositive integers, and M2 >M1.

In a possible design, the transceiver 2801 is configured to: send thefirst boundary bit block to a first device; sequentially send the Ithbit block to the first device; and send the second boundary bit block,the first parity check result, and the second parity check result to thefirst device; or send the second boundary bit block to the first device,and send the first parity check result and the second parity checkresult to a second device.

In a possible design, the transceiver 2801 is configured to: send thesecond boundary bit block at a first moment, and send the first paritycheck result and the second parity check result at a second moment,where the first moment is earlier than the second moment, or the firstmoment is later than the second moment, or the first moment is the sameas the second moment.

In a possible design, the first parity check result and the secondparity check result are stored in the second boundary bit block.

In a possible design, the first parity check result and the secondparity check result are calculated based on a preset check algorithm,where the preset check algorithm is used to keep the first parity checkresult and the second parity check result unchanged when a first bitblock is added to or removed from the N bit blocks, and the first bitblock is a bit block that may be inserted into the N bit blocks ordeleted from the N bit blocks in a transmission process of the N bitblocks.

In a possible design, the preset check algorithm is an xBIP-y algorithm,where x indicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y ≥2.

The processor 2802 is configured to sequentially record every xconsecutive bits of each bit block into a first monitoring section to ay^(th) monitoring section from a first payload bit in the N bit blocks;and determine a 1-bit monitoring code for each monitoring section byusing an odd parity check or an even parity check, to obtain a y-bitmonitoring code, where the y-bit monitoring code includes the firstparity check result and the second parity check result.

In a possible design, the preset check algorithm is a flexBIP-zalgorithm, z indicates a quantity of monitoring sections, not allquantities of consecutive bit-interleaved bits corresponding to themonitoring sections are the same, and the quantities of consecutivebit-interleaved bits respectively corresponding to the z monitoringsections are A1, A2, A3, . . . , and Az, where A1, A2, A3, . . . , Az−1,and Az, and z are positive integers, and z2.

The processor 2802 is configured to record A1 consecutive bits of eachbit block into a first monitoring section from a first payload bit inthe N bit blocks, record A2 consecutive bits after the A1 consecutivebits into a second monitoring section, and record A3 consecutive bitsafter the A2 consecutive bits into a third monitoring section, until Azconsecutive bits after Az−1 consecutive bits are recorded into a z^(th)monitoring section; and determine a 1-bit monitoring code for eachmonitoring section by using an odd parity check or an even parity check,to obtain a z-bit monitoring code, where the z-bit monitoring codeincludes the first parity check result and the second parity checkresult.

In a possible design, the processor 2802 is configured to: determine afirst check result set, where the first check result set includes they-bit monitoring code, or the first check result set includes the z-bitmonitoring code; and the transceiver 2801 is configured to: send thefirst check result set.

Based on a same concept, this application further provides a bit blockstream bit error detection device, where the device may be used toimplement the foregoing corresponding method embodiment in FIG. 12.Therefore, for an implementation of the bit block stream bit errordetection device provided in this embodiment of this application, referto an implementation of the method. Same parts are not described again.

Referring to FIG. 29, an embodiment of this application provides a bitblock stream bit error detection device 2900, including: a transceiver2901 and a processor 2902.

The transceiver 2901 is configured to receive a first boundary bitblock, where the first boundary bit block is used to distinguish T bitblocks to be subsequently received, and T is a positive integer; andsequentially receive an Ith bit block, where I is an integer greaterthan or equal to 1 and less than or equal to T; and receive a secondboundary bit block, where the second boundary bit block is used todistinguish the T bit blocks that have already been received.

The processor 2902 is configured to determine a third parity checkresult and a fourth parity check result, where a check object of thethird parity check result includes m consecutive bits of each bit blockin the T bit blocks, a check object of the fourth parity check resultincludes n consecutive bits of each bit block in the T bit blocks, andat least one of m and n is greater than or equal to 2; and when a firstparity check result and a second parity check result are received byusing the transceiver, determine, based on the first parity check resultand the third parity check result, and the second parity check resultand the fourth parity check result, whether a bit error exists in the Tbit blocks, where a check object of the first parity check resultincludes m consecutive bits of each bit block in N bit blocks, a checkobject of the second parity check result includes n consecutive bits ofeach bit block in the N bit blocks, and N indicates a quantity of bitblocks between the first boundary bit block and the second boundary bitblock when the first parity check result and the second parity checkresult are determined.

In a possible design, the transceiver 2901 is further configured to:when a first parity check result and a second parity check result arenot received, send the third parity check result and the fourth paritycheck result to a second device, where the second device stores thefirst parity check result and the second parity check result.

In a possible design, a type of each bit block is an M1/M2 bit block, M1indicates a quantity of payload bits in each bit block, M2 indicates atotal quantity of bits in each bit block, M2−M1 indicates a quantity ofsynchronization header bits at a header of each bit block, M1 and M2 arepositive integers, and M2 >M1.

In a possible design, the transceiver 2901 is configured to: receive thesecond boundary bit block at a first moment; and receive the firstparity check result and the second parity check result at a secondmoment, where the first moment is earlier than the second moment, or thefirst moment is later than the second moment, or the first moment is thesame as the second moment.

In a possible design, the first parity check result and the secondparity check result are stored in the second boundary bit block.

In a possible design, the third parity check result and the fourthparity check result are calculated based on a preset check algorithm,where the preset check algorithm is used to keep the third parity checkresult and the fourth parity check result unchanged when a first bitblock is added to or removed from the T bit blocks, and the first bitblock is a bit block that may be inserted into the T bit blocks ordeleted from the T bit blocks in a transmission process of the T bitblocks.

In a possible design, the preset check algorithm is an xBIP-y algorithm,where x indicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y ≥2; and the processor 2902 is configured to sequentiallyrecord every x consecutive bits of each bit block into a firstmonitoring section to a y^(th) monitoring section from a first payloadbit in the T bit blocks; and determine a 1-bit monitoring code for eachmonitoring section by using an odd parity check or an even parity check,to obtain a y-bit monitoring code, where the y-bit monitoring codeincludes the third parity check result and the fourth parity checkresult.

In a possible design, the preset check algorithm is a flexBIP-zalgorithm, z indicates a quantity of monitoring sections, not allquantities of consecutive bit-interleaved bits corresponding to themonitoring sections are the same, and the quantities of consecutivebit-interleaved bits respectively corresponding to the z monitoringsections are A1, A2, A3, . . . , and Az, where A1, A2, A3, . . . , Az−1,and Az, and z are positive integers, and z 2.

The processor 2902 is configured to record A1 consecutive bits of eachbit block into a first monitoring section from a first payload bit inthe T bit blocks, record A2 consecutive bits after the A1 consecutivebits into a second monitoring section, and record A3 consecutive bitsafter the A2 consecutive bits into a third monitoring section, until Azconsecutive bits after Az−1 consecutive bits are recorded into a z^(th)monitoring section; and determine a 1-bit monitoring code for eachmonitoring section by using an odd parity check or an even parity check,to obtain a z-bit monitoring code, where the z-bit monitoring codeincludes the third parity check result and the fourth parity checkresult.

In a possible design, the processor 2902 is configured to: if it isdetermined that the first parity check result is the same as the thirdparity check result, and the second parity check result is the same asthe fourth parity check result, determine that no bit error exists inthe T bit blocks; or if it is determined that the first parity checkresult is different from the third parity check result, and/or thesecond parity check result is different from the fourth parity checkresult, determine that a bit error exists in the T bit blocks.

In a possible design, the transceiver 2901 is configured to: receive afirst check result set, where the first check result set is calculatedbased on an xBIP-y algorithm, and a y-bit monitoring code included inthe first check result set includes the first parity check result andthe second parity check result.

The processor 2902 is configured to determine a second check result set,where the second parity check result set is calculated based on thexBIP-y algorithm, and a y-bit monitoring code included in the secondcheck result set includes the third parity check result and the fourthparity check result; and determine, based on the first check result setand the second check result set, whether a bit error exists in the T bitblocks.

In a possible design, the transceiver 2901 is configured to: receive afirst check result set, where the first check result set is calculatedbased on a flexBIP-z algorithm, and a z-bit monitoring code included inthe first check result set includes the first parity check result andthe second parity check result.

The processor 2902 is configured to determine a second check result set,where the second check result set is calculated based on the flexBIP-zalgorithm, and a z-bit monitoring code included in the second checkresult set includes the third parity check result and the fourth paritycheck result; and determine, based on the first check result set and thesecond check result set, whether a bit error exists in the T bit blocks.

In a possible design, the processor 2902 is configured to: if it isdetermined that the first check result set is the same as the secondcheck result set, determine that no bit error exists in the T bitblocks; or if it is determined that the first check result set isdifferent from the second check result set, determine that a bit errorexists in the T bit blocks.

Based on a same concept, this application further provides a bit blockstream bit error detection device, where the device may be used toimplement the foregoing corresponding method embodiment in FIG. 13.Therefore, for an implementation of the bit block stream bit errordetection device provided in this embodiment of this application, referto an implementation of the method. Same parts are not described again.

Referring to FIG. 30, an embodiment of this application provides a bitblock stream bit error detection device 3000, including: a transceiver3001 and a processor 3002.

The processor 3002 is configured to determine a to-be-detected sectionbased on a start byte in a start block in a bit block stream and an endbyte in an end block corresponding to the start block; and calculate afirst check result based on the to-be-detected section.

The transceiver 3001 is configured to send the first check result andthe bit block stream.

In a possible design, the bit block stream includes at least one M1/M2bit block, where M1 indicates a quantity of payload bits in each bitblock, M2 indicates a total quantity of bits in each bit block, M2−M1indicates a quantity of synchronization header bits at a header of eachbit block, M1 and M2 are positive integers, and M2 >M1.

In a possible design, the transceiver 3001 is configured to: send thefirst check result and the bit block stream to a second device; or sendthe first check result to a third device, and send the bit block streamto the second device.

In a possible design, the processor 3002 is further configured to:before the transceiver sends the first check result and the bit blockstream to the second device, store the first check result into the endblock, to obtain an updated end block; or store the first check resultinto a check result storage block, and delete any first bit block in thebit block stream, where the check result storage block is a newly addedblock located before the end block, and the first bit block is a bitblock that may be inserted into the bit block stream or deleted from thebit block stream in a transmission process of the bit block stream.

In a possible design, the processor 3002 is configured to: when aquantity of bytes occupied by the first check result is greater than orequal to a quantity of target bytes, store the first check result at aposition before the end byte in the end block, move the end byte into anewly added block after the end block based on the quantity of bytesoccupied by the first check result, delete any first bit block in thebit block stream, and use the newly added block in which the end byte islocated after being moved as an updated end block; or when a quantity ofbytes occupied by the first check result is less than the quantity oftarget bytes, store the first check result at a position before the endbyte in the end block, backward move, based on the quantity of bytesoccupied by the first check result, the end byte by the quantity ofbytes occupied by the first check result, and use a bit block in whichthe end byte is located after being moved as an updated end block, wherethe quantity of target bytes is 1 plus a quantity of bytes located afterthe end byte in the end block.

Based on a same concept, this application further provides a bit blockstream bit error detection device, where the device may be used toimplement the foregoing corresponding method embodiment in FIG. 21.Therefore, for an implementation of the bit block stream bit errordetection device provided in this embodiment of this application, referto an implementation of the method. Same parts are not described again.

Referring to FIG. 31, an embodiment of this application provides a bitblock stream bit error detection device 3100, including: a transceiver3101 and a processor 3102.

The processor 3102 is configured to determine a to-be-detected sectionbased on a start byte in a start block in a bit block stream and an endbyte in an end block corresponding to the start block; and calculate asecond check result based on the to-be-detected section; and when afirst check result is received by using the transceiver 3101, determine,based on the first check result and the second check result, whether abit error exists in the to-be-detected section.

In a possible design, the bit block stream includes at least one M1/M2bit block, where M1 indicates a quantity of payload bits in each bitblock, M2 indicates a total quantity of bits in each bit block, M2−M1indicates a quantity of synchronization header bits at a header of eachbit block, M1 and M2 are positive integers, and M2 >M1.

In a possible design, the processor 3102 is configured to: if the firstcheck result is received by using the transceiver, and the first checkresult is stored in the end block, delete the first check result fromthe end block, to obtain an updated end block, and use bytes between thestart byte in the start block and an end byte in the updated end blockas the to-be-detected section; and if the first check result is receivedby using the transceiver, and the first check result is stored in acheck result storage block, delete the check result storage block fromthe bit block stream, to obtain an updated bit block stream, and usebytes between the start byte in the start block in the updated bit blockstream and the end byte in the end block as the to-be-detected section,where the check result storage block is located before the end block; orwhen the first check result is not received, use bytes between the startbyte in the start block in the bit block stream and the end byte in theend block as the to-be-detected section.

In a possible design, the transceiver 3101 is further configured to:when the first check result is not received, send the second checkresult to a third device, where the third device stores the first checkresult.

In a possible design, the processor 3102 is configured to: if it isdetermined that the first check result is the same as the second checkresult, determine that no bit error exists in the to-be-detectedsection; or if it is determined that the first check result is differentfrom the second check result, determine that a bit error exists in theto-be-detected section.

In a possible design, the processor 3102 is configured to: when aquantity of bytes occupied by the first check result is greater than orequal to a quantity of target bytes, move the end byte into a bit blockbefore the end block based on the quantity of bytes occupied by thefirst check result, add a new first bit block to the bit block stream,and use a bit block in which the end byte is located after being movedas an updated end block; or when a quantity of bytes occupied by thefirst check result is less than the quantity of target bytes, forwardmove, based on the quantity of bytes occupied by the first check result,the end byte by the quantity of bytes occupied by the first checkresult, and use a bit block in which the end byte is located after beingmoved as an updated end block, where the quantity of target bytes is 1plus a quantity of bytes located before the end byte in the end block.

In conclusion, the embodiments of this application provide a bit blockstream bit error detection method, where the method includes: sending,by a transmitting device, a first boundary bit block, where the firstboundary bit block is used to distinguish N bit blocks to besubsequently sent, and N is a positive integer; and sequentially sendingan Ith bit block, where I is an integer greater than or equal to 1 andless than or equal to N; determining a first parity check result and asecond parity check result, where a check object of the first paritycheck result includes m consecutive bits of each bit block in the N bitblocks, a check object of the second parity check result includes nconsecutive bits of each bit block in the N bit blocks, and at least oneof m and n is greater than or equal to 2; and sending a second boundarybit block, the first parity check result, and the second parity checkresult, where the second boundary bit block is used to distinguish the Nbit blocks that have been sent; in addition, receiving, by a receivingdevice, a first boundary bit block, where the first boundary bit blockis used to distinguish T bit blocks to be subsequently received, and Tis a positive integer; sequentially receiving an Ith bit block, where Iis an integer greater than or equal to 1 and less than or equal to T;receiving a second boundary bit block, where the second boundary bitblock is used to distinguish the T bit blocks that have already beenreceived; determining a third parity check result and a fourth paritycheck result, where a check object of the third parity check resultincludes m consecutive bits of each bit block in the T bit blocks, acheck object of the fourth parity check result includes n consecutivebits of each bit block in the T bit blocks, and at least one of m and nis greater than or equal to 2; and when a first parity check result anda second parity check result are received, determining, based on thefirst parity check result and the third parity check result, and thesecond parity check result and the fourth parity check result, whether abit error exists in the T bit blocks, where a check object of the firstparity check result includes m consecutive bits of each bit block in Nbit blocks, a check object of the second parity check result includes nconsecutive bits of each bit block in the N bit blocks, and N indicatesa quantity of bit blocks between the first boundary bit block and thesecond boundary bit block when the first parity check result and thesecond parity check result are determined. Therefore, by using themethod provided in the embodiments of this application, error or biterror detection on a network path of an M/N bit block can be fullyimplemented, with no impact on a user service; bearer efficiency is100%, and a bit block that is inserted or deleted due to synchronizationin a transfer process can be tolerated; in addition, a detection period(that is, a quantity of bit blocks between the two boundary bit blocks)and detection precision (that is, a preset algorithm) can be dynamicallyconfigured according to a requirement. In addition, the detection methodcan not only be used for a to-be-checked bit block stream whose path isan end-to-end path, but can also be used for a to-be-checked bit blockstream whose path is a non-end-to-end path. Therefore, the methodprovided in the embodiments of this application can be used to resolveproblems of relatively high implementation difficulty and relatively lowbearer efficiency of a bit error detection method in an M/N bit blockswitching scenario.

An embodiment of this application further provides a bit block streambit error detection method, where the method includes: determining, by afirst device, a to-be-detected section based on a start byte in a startblock in a bit block stream and an end byte in an end blockcorresponding to the start block; and calculating, by the first device,a first check result based on the to-be-detected section; and sending,by the first device, the first check result and the bit block stream.For example, an algorithm used when the first device calculates thefirst check result may be CRC-x or BIP-x, the first check result isrecorded as B, and B may be one or more bytes. A second devicedetermines, based on the start byte in the start block in the bit blockstream and the end byte in the end block corresponding to the startblock, the to-be-detected section; and the second device calculates asecond check result based on the to-be- detected section. When thesecond device receives the first check result, the second devicedetermines, based on the first check result and the second check result,whether a bit error exists in the to-be-detected section. Therefore, byusing the method provided in this embodiment of this application, erroror bit error detection on a network path of an M/N bit block can befully implemented, with little impact on a user service; bearerefficiency is close to bearer efficiency of SDH/OTN, and superior tobearer efficiency of a bit error detection method provided in thecurrent technology; and an implementation procedure is simple, and easyto implement.

A person skilled in the art should understand that the embodiments ofthis application may be provided as a method, a system, or a computerprogram product. Therefore, the embodiments of this application may usea form of hardware only embodiments, software only embodiments, orembodiments with a combination of software and hardware. Moreover, theembodiments of this application may use a form of a computer programproduct that is implemented on one or more computer-usable storage media(including but not limited to a magnetic disk storage, a CD-ROM, anoptical memory, and the like) that include computer-usable program code.

The embodiments of this application are described with reference to theflowcharts and/or block diagrams of the method, the device (system), andthe computer program product according to the embodiments of thisapplication. It should be understood that computer program instructionsmay be used to implement each process and/or each block in theflowcharts and/or the block diagrams and a combination of a processand/or a block in the flowcharts and/or the block diagrams. Thesecomputer program instructions may be provided for a general-purposecomputer, a special-purpose computer, an embedded processor, or aprocessor of any other programmable data processing device to generate amachine, so that the instructions executed by a computer or a processorof any other programmable data processing device generate an apparatusfor implementing a specific function in one or more processes in theflowcharts and/or in one or more blocks in the block diagrams.

These computer program instructions may be stored in a computer-readablememory that can instruct the computer or any other programmable dataprocessing device to work in a specific manner, so that the instructionsstored in the computer-readable memory generate an artifact thatincludes an instruction apparatus. The instruction apparatus implementsa specific function in one or more processes in the flowcharts and/or inone or more blocks in the block diagrams.

These computer program instructions may be loaded onto a computer oranother programmable data processing device, so that a series ofoperations and steps are performed on the computer or the anotherprogrammable device, thereby generating computer-implemented processing.Therefore, the instructions executed on the computer or the anotherprogrammable device provide steps for implementing a specific functionin one or more processes in the flowcharts and/or in one or more blocksin the block diagrams.

Obviously, a person skilled in the art can make various modificationsand variations to the embodiments of this application without departingfrom the spirit and scope of this application. Therefore, thisapplication is intended to cover these modifications and variationsprovided that they fall within the scope of protection defined by thefollowing claims and their equivalent technologies.

1.-20. (canceled)
 21. A method, comprising: sending a first boundary bitblock, wherein the first boundary bit block is usable to distinguish Nbit blocks to be sent subsequent to the first boundary bit block, and Nis a positive integer; for each integer value of I from 1 to N, sendingan Ith bit block, to send the N bit blocks, wherein the bit blocks ofthe N bit blocks are sequentially sent; determining a first parity checkresult and a second parity check result, wherein a check object of thefirst parity check result comprises m consecutive bits of at least onebit block in the N bit blocks, a check object of the second parity checkresult comprises n consecutive bits of at least one bit block in the Nbit blocks, and at least one of m or n is greater than or equal to 2;and sending a second boundary bit block, the first parity check result,and the second parity check result, wherein the second boundary bitblock is usable to distinguish the N bit blocks that were sent beforethe second boundary bit block is sent.
 22. The method according to claim21, wherein a type of each bit block is an M1/M2 bit block, M1 indicatesa quantity of payload bits in each bit block, M2 indicates a totalquantity of bits in each bit block, M2−M1 indicates a quantity ofsynchronization header bits at a header of each bit block, M1 and M2 arepositive integers, and M2 >M1.
 23. The method according to claim 21,wherein the first parity check result and the second parity check resultare calculated based on a preset check algorithm, the preset checkalgorithm is used to keep the first parity check result and the secondparity check result unchanged when a first bit block is added to orremoved from the N bit blocks, and the first bit block is a bit blockthat is inserted into the N bit blocks or deleted from the N bit blocksin a transmission process of the N bit blocks.
 24. The method accordingto claim 23, wherein the preset check algorithm is an xBIP-y algorithm,x indicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y ≥2; and wherein determining the first parity checkresult and the second parity check result comprises: sequentiallyrecording every x consecutive bits of at least one bit block into afirst monitoring section to a yth monitoring section from a firstpayload bit in the N bit blocks; and determining a 1-bit monitoring codefor each monitoring section using an odd parity check or an even paritycheck, to obtain a y-bit monitoring code, wherein the y-bit monitoringcode comprises the first parity check result and the second parity checkresult.
 25. The method according to claim 23, wherein the preset checkalgorithm is a flexBIP-z algorithm, z indicates a quantity of monitoringsections, not all quantities of consecutive bit-interleaved bitscorresponding to the monitoring sections are the same, and thequantities of consecutive bit-interleaved bits respectivelycorresponding to the z monitoring sections are A1, A2, A3, . . . , Az−1,and Az, wherein A1, A2, A3, . . . , Az−1, and Az, and z are positiveintegers, and z2; and wherein determining the first parity check resultand the second parity check result comprises: recording A1 consecutivebits of at least one bit block into a first monitoring section from afirst payload bit in the N bit blocks, recording A2 consecutive bitsafter the A1 consecutive bits into a second monitoring section, andrecording A3 consecutive bits after the A2 consecutive bits into a thirdmonitoring section, until Az consecutive bits after Az−1 consecutivebits are recorded into a zth monitoring section; and determining a 1-bitmonitoring code for each monitoring section using an odd parity check oran even parity check, to obtain a z-bit monitoring code, wherein thez-bit monitoring code comprises the first parity check result and thesecond parity check result.
 26. The method according to claim 25,wherein determining the first parity check result and the second paritycheck result comprises: determining a first check result set, whereinthe first check result set comprises the z-bit monitoring code; andwherein sending the first parity check result and the second paritycheck result comprises: sending the first check result set.
 27. Amethod, comprising: receiving a first boundary bit block, wherein thefirst boundary bit block is usable to distinguish T bit blocks to bereceived subsequently to receiving the first boundary bit block, and Tis a positive integer; for each integer value of I from 1 to T,receiving an Ith bit block to receive the T bit blocks, wherein bitblocks of the T bit blocks are sequentially received; receiving a secondboundary bit block, wherein the second boundary bit block is usable todistinguish the T bit blocks that were received previously to receivingthe second boundary bit block; determining a third parity check resultand a fourth parity check result, wherein a check object of the thirdparity check result comprises m consecutive bits of at least one bitblock in the T bit blocks, a check object of the fourth parity checkresult comprises n consecutive bits of at least one bit block in the Tbit blocks, and at least one of m or n is greater than or equal to 2;and when a first parity check result and a second parity check resultare received, determining, based on the first parity check result, thethird parity check result, the second parity check result, and thefourth parity check result, whether a bit error exists in the T bitblocks, wherein a check object of the first parity check resultcomprises m consecutive bits of at least one bit block in N bit blocks,a check object of the second parity check result comprises n consecutivebits of at least one bit block in the N bit blocks, and N indicates aquantity of bit blocks between the first boundary bit block and thesecond boundary bit block when the first parity check result and thesecond parity check result are determined.
 28. The method according toclaim 27, wherein a type of each bit block is an M1/M2 bit block, M1indicates a quantity of payload bits in each bit block, M2 indicates atotal quantity of bits in each bit block, M2−M1 indicates a quantity ofsynchronization header bits at a header of each bit block, M1 and M2 arepositive integers, and M2 >M1.
 29. The method according to claim 27,wherein the third parity check result and the fourth parity check resultare calculated based on a preset check algorithm, the preset checkalgorithm is used to keep the third parity check result and the fourthparity check result unchanged when a first bit block is added to orremoved from the T bit blocks, and the first bit block is a bit blockthat is inserted into the T bit blocks or deleted from the T bit blocksin a transmission process of the T bit blocks.
 30. The method accordingto claim 29, wherein the preset check algorithm is an xBIP-y algorithm,x indicates a quantity of consecutive bit-interleaved bits, x isdetermined based on a code type definition of the first bit block, yindicates a quantity of monitoring sections, x and y are positiveintegers, and y ≥2; and wherein determining the third parity checkresult and the fourth parity check result comprises: sequentiallyrecording every x consecutive bits of at least one bit block into afirst monitoring section to a yth monitoring section from a firstpayload bit in the T bit blocks; and determining a 1-bit monitoring codefor each monitoring section using an odd parity check or an even paritycheck, to obtain a y-bit monitoring code, wherein the y-bit monitoringcode comprises the third parity check result and the fourth parity checkresult.
 31. The method according to claim 29, wherein the preset checkalgorithm is a flexBIP-z algorithm, z indicates a quantity of monitoringsections, not all quantities of consecutive bit-interleaved bitscorresponding to the monitoring sections are the same, and thequantities of consecutive bit-interleaved bits respectivelycorresponding to the z monitoring sections are A1, A2, A3, . . . , Az−1,and Az, wherein A1, A2, A3, . . . , Az−1, and Az, and z are positiveintegers, and z2; and wherein determining the third parity check resultand the fourth parity check result comprises: recording A1 consecutivebits of at least one bit block into a first monitoring section from afirst payload bit in the T bit blocks, recording A2 consecutive bitsafter the A1 consecutive bits into a second monitoring section, andrecording A3 consecutive bits after the A2 consecutive bits into a thirdmonitoring section, until Az consecutive bits after Az−1 consecutivebits are recorded into a zth monitoring section; and determining a 1-bitmonitoring code for each monitoring section using an odd parity check oran even parity check, to obtain a z-bit monitoring code, wherein thez-bit monitoring code comprises the third parity check result and thefourth parity check result.
 32. The method according to claim 29,wherein receiving the first parity check result and the second paritycheck result comprises: receiving a first check result set, wherein thefirst check result set is calculated based on an xBIP-y algorithm, and ay-bit monitoring code comprised in the first check result set comprisesthe first parity check result and the second parity check result;wherein determining the third parity check result and the fourth paritycheck result comprises: determining a second check result set, whereinthe second parity check result set is calculated based on the xBIP-yalgorithm, and a y-bit monitoring code comprised in the second checkresult set comprises the third parity check result and the fourth paritycheck result; and when the first parity check result and the secondparity check result are received, the determining, based on the firstparity check result, the third parity check result, the second paritycheck result, and the fourth parity check result, whether a bit errorexists in the T bit blocks comprises: determining, based on the firstcheck result set and the second check result set, whether a bit errorexists in the T bit blocks.
 33. The method according to claim 32,wherein determining, based on the first check result set and the secondcheck result set, whether a bit error exists in the T bit blockscomprises: in response to determining that the first check result set isthe same as the second check result set, determining that no bit errorexists in the T bit blocks; or in response to determining that the firstcheck result set is different from the second check result set,determining that a bit error exists in the T bit blocks.
 34. The methodaccording to claim 29, wherein receiving the first parity check resultand the second parity check result comprises: receiving a first checkresult set, wherein the first check result set is calculated based on aflexBIP-z algorithm, and a z-bit monitoring code comprised in the firstcheck result set comprises the first parity check result and the secondparity check result; wherein determining the third parity check resultand the fourth parity check result comprises: determining a second checkresult set, wherein the second check result set is calculated based onthe flexBIP-z algorithm, and a z-bit monitoring code comprised in thesecond check result set comprises the third parity check result and thefourth parity check result; and wherein when the first parity checkresult and the second parity check result are received, determining,based on the first parity check result, the third parity check result,the second parity check result, and the fourth parity check result,whether a bit error exists in the T bit blocks comprises: determining,based on the first check result set and the second check result set,whether a bit error exists in the T bit blocks.
 35. A device,comprising: a transceiver, configured to: send a first boundary bitblock, wherein the first boundary bit block is usable to distinguish Nbit blocks to be sent subsequently to sending the first boundary bitblock, and N is a positive integer; and for each integer value of I from1 to N, send an I^(th) bit block, to send the N bit blocks, wherein bitblocks of the N bit blocks are sequentially sent; and a processor,configured to determine a first parity check result and a second paritycheck result, wherein a check object of the first parity check resultcomprises m consecutive bits of at least one bit block in the N bitblocks, a check object of the second parity check result comprises nconsecutive bits of at least one bit block in the N bit blocks, and atleast one of m or n is greater than or equal to 2; and wherein thetransceiver is further configured to send a second boundary bit block,the first parity check result, and the second parity check result,wherein the second boundary bit block is usable to distinguish the N bitblocks that were sent before the second boundary bit block is sent. 36.The device according to claim 35, wherein a type of each bit block is anM1/M2 bit block, M1 indicates a quantity of payload bits in each bitblock, M2 indicates a total quantity of bits in each bit block, M2−M1indicates a quantity of synchronization header bits at a header of eachbit block, M1 and M2 are positive integers, and M2 >M1.
 37. The deviceaccording to claim 35, wherein the first parity check result and thesecond parity check result are calculated based on a preset checkalgorithm, the preset check algorithm is used to keep the first paritycheck result and the second parity check result unchanged when a firstbit block is added to or removed from the N bit blocks, and the firstbit block is a bit block that is inserted into the N bit blocks ordeleted from the N bit blocks in a transmission process of the N bitblocks.
 38. The device according to claim 37, wherein the preset checkalgorithm is an xBIP-y algorithm, x indicates a quantity of consecutivebit-interleaved bits, x is determined based on a code type definition ofthe first bit block, y indicates a quantity of monitoring sections, xand y are positive integers, and y ≥2; and wherin the processor isconfigured to: sequentially record every x consecutive bits of at leastone bit block into a first monitoring section to a yth monitoringsection from a first payload bit in the N bit blocks; and determine a1-bit monitoring code for each monitoring section by using an odd paritycheck or an even parity check, to obtain a y-bit monitoring code,wherein the y-bit monitoring code comprises the first parity checkresult and the second parity check result.
 39. The device according toclaim 38, wherein the processor is configured to: determine a firstcheck result set, wherein the first check result set comprises the y-bitmonitoring code; and wherein the transceiver is configured to: send thefirst check result set.
 40. The device according to claim 37, whereinthe preset check algorithm is a flexBIP-z algorithm, z indicates aquantity of monitoring sections, not all quantities of consecutivebit-interleaved bits corresponding to the monitoring sections are thesame, and the quantities of consecutive bit-interleaved bitsrespectively corresponding to the z monitoring sections are A1, A2, A3,. . . , Az−1, and Az, wherein A1, A2, A3, . . . , Az−1, and Az, and zare positive integers, and z ≥2; and wherein the processor is configuredto: record A1 consecutive bits of at least one bit block into a firstmonitoring section from a first payload bit in the N bit blocks, recordA2 consecutive bits after the A1 consecutive bits into a secondmonitoring section, and record A3 consecutive bits after the A2consecutive bits into a third monitoring section, until Az consecutivebits after Az−1 consecutive bits are recorded into a zth monitoringsection; and determine a 1-bit monitoring code for each monitoringsection using an odd parity check or an even parity check, to obtain az-bit monitoring code, wherein the z-bit monitoring code comprises thefirst parity check result and the second parity check result.